pid/zone_interface.hpp - openbmc/phosphor-pid-control - Gitiles

 #pragma once

 #include "sensors/sensor.hpp"

 #include <string>

 namespace pid_control
 {

 /**
  * In a Zone you have a set of PIDs which feed each other.  Fan PIDs are fed set
  * points from Thermal PIDs.
  */
 class ZoneInterface
 {
   public:
     virtual ~ZoneInterface() = default;

     /** Get Current Zone ID */
     virtual int64_t getZoneID(void) const = 0;

     /** If the zone implementation supports logging, initialize the log. */
     virtual void initializeLog(void) = 0;
     /** If the zone implementation supports logging, write string to log. */
     virtual void writeLog(const std::string& value) = 0;

     /** Return a pointer to the sensor specified by name. */
     virtual Sensor* getSensor(const std::string& name) = 0;

     /* updateFanTelemetry() and updateSensors() both clear the failsafe state
      * for a sensor if it's no longer in that state.
      */
     /** For each fan input in the zone, read each to update the cachedValue and
      * check if the fan is beyond its timeout to trigger a failsafe condition.
      */
     virtual void updateFanTelemetry(void) = 0;
     /** For each thermal input in the zone, read each to update the cachedValue
      * and check if the sensor is beyond its timeout to trigger a failsafe
      * condition.
      */
     virtual void updateSensors(void) = 0;
     /** For each fan and thermal input in the zone, set the cachedValue to 0 and
      * set the input as failsafe - to default the zone to failsafe before it
      * starts processing values to control fans.
      */
     virtual void initializeCache(void) = 0;

     /** Optionally adds fan outputs to an output cache, which is different
      * from the input cache accessed by getCachedValue(), so it is possible
      * to have entries with the same name in both the output cache and
      * the input cache. The output cache is used for logging, to show
      * the PWM values determined by the PID loop, next to the resulting RPM.
      */
     virtual void setOutputCache(std::string_view name,
                                 const ValueCacheEntry& values) = 0;

     /** Return cached value for sensor by name. */
     virtual double getCachedValue(const std::string& name) = 0;
     /** Return cached values, both scaled and original unscaled values,
      * for sensor by name. Subclasses can add trivial return {value, value},
      * for subclasses that only implement getCachedValue() and do not care
      * about maintaining the distinction between scaled and unscaled values.
      */
     virtual ValueCacheEntry getCachedValues(const std::string& name) = 0;

     /** Add a set point value for the Max Set Point computation. */
     virtual void addSetPoint(double setpoint, const std::string& name) = 0;
     /** Clear all set points specified via addSetPoint */
     virtual void clearSetPoints(void) = 0;

     /** Add maximum RPM value to drive fan pids. */
     virtual void addRPMCeiling(double ceiling) = 0;
     /** Clear any RPM value set with addRPMCeiling. */
     virtual void clearRPMCeilings(void) = 0;

     /** Compute the value returned by getMaxSetPointRequest - called from the
      * looping mechanism before triggering any Fan PIDs. The value computed is
      * used by each fan PID.
      */
     virtual void determineMaxSetPointRequest(void) = 0;
     /** Given the set points added via addSetPoint, return the maximum value -
      * called from the PID loop that uses that value to drive the fans.
      */
     virtual double getMaxSetPointRequest() const = 0;

     /** Return if the zone has any sensors in fail safe mode. */
     virtual bool getFailSafeMode() const = 0;
     /** Return the rpm or pwm percent value to drive fan pids when zone is in
      * fail safe.
      */
     virtual double getFailSafePercent() const = 0;

     /** Return the zone's cycle time settings */
     virtual uint64_t getCycleIntervalTime(void) const = 0;
     virtual uint64_t getUpdateThermalsCycle(void) const = 0;

     /** Return if the zone is set to manual mode.  false equates to automatic
      * mode (the default).
      */
     virtual bool getManualMode(void) const = 0;

     /** Returns true if a redundant fan PWM write is needed. Redundant write
      * is used when returning the fan to automatic mode from manual mode.
      */
     virtual bool getRedundantWrite(void) const = 0;

     /** For each fan pid, do processing. */
     virtual void processFans(void) = 0;
     /** For each thermal pid, do processing. */
     virtual void processThermals(void) = 0;
 };

 } // namespace pid_control
	#pragma once

	#include "sensors/sensor.hpp"

	#include <string>

	namespace pid_control
	{

	/**
	* In a Zone you have a set of PIDs which feed each other. Fan PIDs are fed set
	* points from Thermal PIDs.
	*/
	class ZoneInterface
	{
	public:
	virtual ~ZoneInterface() = default;

	/** Get Current Zone ID */
	virtual int64_t getZoneID(void) const = 0;

	/** If the zone implementation supports logging, initialize the log. */
	virtual void initializeLog(void) = 0;
	/** If the zone implementation supports logging, write string to log. */
	virtual void writeLog(const std::string& value) = 0;

	/** Return a pointer to the sensor specified by name. */
	virtual Sensor* getSensor(const std::string& name) = 0;

	/* updateFanTelemetry() and updateSensors() both clear the failsafe state
	* for a sensor if it's no longer in that state.
	*/
	/** For each fan input in the zone, read each to update the cachedValue and
	* check if the fan is beyond its timeout to trigger a failsafe condition.
	*/
	virtual void updateFanTelemetry(void) = 0;
	/** For each thermal input in the zone, read each to update the cachedValue
	* and check if the sensor is beyond its timeout to trigger a failsafe
	* condition.
	*/
	virtual void updateSensors(void) = 0;
	/** For each fan and thermal input in the zone, set the cachedValue to 0 and
	* set the input as failsafe - to default the zone to failsafe before it
	* starts processing values to control fans.
	*/
	virtual void initializeCache(void) = 0;

	/** Optionally adds fan outputs to an output cache, which is different
	* from the input cache accessed by getCachedValue(), so it is possible
	* to have entries with the same name in both the output cache and
	* the input cache. The output cache is used for logging, to show
	* the PWM values determined by the PID loop, next to the resulting RPM.
	*/
	virtual void setOutputCache(std::string_view name,
	const ValueCacheEntry& values) = 0;

	/** Return cached value for sensor by name. */
	virtual double getCachedValue(const std::string& name) = 0;
	/** Return cached values, both scaled and original unscaled values,
	* for sensor by name. Subclasses can add trivial return {value, value},
	* for subclasses that only implement getCachedValue() and do not care
	* about maintaining the distinction between scaled and unscaled values.
	*/
	virtual ValueCacheEntry getCachedValues(const std::string& name) = 0;

	/** Add a set point value for the Max Set Point computation. */
	virtual void addSetPoint(double setpoint, const std::string& name) = 0;
	/** Clear all set points specified via addSetPoint */
	virtual void clearSetPoints(void) = 0;

	/** Add maximum RPM value to drive fan pids. */
	virtual void addRPMCeiling(double ceiling) = 0;
	/** Clear any RPM value set with addRPMCeiling. */
	virtual void clearRPMCeilings(void) = 0;

	/** Compute the value returned by getMaxSetPointRequest - called from the
	* looping mechanism before triggering any Fan PIDs. The value computed is
	* used by each fan PID.
	*/
	virtual void determineMaxSetPointRequest(void) = 0;
	/** Given the set points added via addSetPoint, return the maximum value -
	* called from the PID loop that uses that value to drive the fans.
	*/
	virtual double getMaxSetPointRequest() const = 0;

	/** Return if the zone has any sensors in fail safe mode. */
	virtual bool getFailSafeMode() const = 0;
	/** Return the rpm or pwm percent value to drive fan pids when zone is in
	* fail safe.
	*/
	virtual double getFailSafePercent() const = 0;

	/** Return the zone's cycle time settings */
	virtual uint64_t getCycleIntervalTime(void) const = 0;
	virtual uint64_t getUpdateThermalsCycle(void) const = 0;

	/** Return if the zone is set to manual mode. false equates to automatic
	* mode (the default).
	*/
	virtual bool getManualMode(void) const = 0;

	/** Returns true if a redundant fan PWM write is needed. Redundant write
	* is used when returning the fan to automatic mode from manual mode.
	*/
	virtual bool getRedundantWrite(void) const = 0;

	/** For each fan pid, do processing. */
	virtual void processFans(void) = 0;
	/** For each thermal pid, do processing. */
	virtual void processThermals(void) = 0;
	};

	} // namespace pid_control