physical.hpp - openbmc/phosphor-led-sysfs - Gitiles

 #pragma once

 #include "sysfs.hpp"

 #include <fstream>
 #include <sdbusplus/bus.hpp>
 #include <sdbusplus/server/object.hpp>
 #include <string>
 #include <xyz/openbmc_project/Led/Physical/server.hpp>

 namespace phosphor
 {
 namespace led
 {
 /** @brief Assert LED by writing 255 */
 constexpr unsigned long ASSERT = 255;

 /** @brief De-assert by writing "0" */
 constexpr unsigned long DEASSERT = 0;

 /** @class Physical
  *  @brief Responsible for applying actions on a particular physical LED
  */
 class Physical : public sdbusplus::server::object::object<
                      sdbusplus::xyz::openbmc_project::Led::server::Physical>
 {
   public:
     Physical() = delete;
     ~Physical() = default;
     Physical(const Physical&) = delete;
     Physical& operator=(const Physical&) = delete;
     Physical(Physical&&) = delete;
     Physical& operator=(Physical&&) = delete;

     /** @brief Constructs LED object. Argument 'true' says that we hold off
      *   from sending the signals since we need to do some house keeping and
      *   only when we finish that, we are considered active and can then
      *   broadcast the signal.
      *
      * @param[in] bus       - system dbus handler
      * @param[in] objPath   - The Dbus path that hosts physical LED
      * @param[in] ledPath   - sysfs path where this LED is exported
      */
     Physical(sdbusplus::bus::bus& bus, const std::string& objPath,
              SysfsLed& led) :

         sdbusplus::server::object::object<
             sdbusplus::xyz::openbmc_project::Led::server::Physical>(
             bus, objPath.c_str(), true),
         led(led)
     {
         // Suppose this is getting launched as part of BMC reboot, then we
         // need to save what the micro-controller currently has.
         setInitialState();

         // We are now ready.
         emit_object_added();
     }

     /** @brief Overloaded State Property Setter function
      *
      *  @param[in] value   -  One of OFF / ON / BLINK
      *  @return            -  Success or exception thrown
      */
     Action state(Action value) override;

   private:
     /** @brief Associated LED implementation
      */
     SysfsLed& led;

     /** @brief Frequency range that the LED can operate on.
      *  Will be removed when frequency is put into interface
      */
     uint32_t frequency;

     /** @brief reads sysfs and then setsup the parameteres accordingly
      *
      *  @return None
      */
     void setInitialState();

     /** @brief Applies the user triggered action on the LED
      *   by writing to sysfs
      *
      *  @param [in] current - Current state of LED
      *  @param [in] request - Requested state
      *
      *  @return None
      */
     void driveLED(Action current, Action request);

     /** @brief Sets the LED to either ON or OFF state
      *
      *  @param [in] action - Requested action. Could be OFF or ON
      *  @return None
      */
     void stableStateOperation(Action action);

     /** @brief Sets the LED to BLINKING
      *
      *  @return None
      */
     void blinkOperation();
 };

 } // namespace led
 } // namespace phosphor
	#pragma once

	#include "sysfs.hpp"

	#include <fstream>
	#include <sdbusplus/bus.hpp>
	#include <sdbusplus/server/object.hpp>
	#include <string>
	#include <xyz/openbmc_project/Led/Physical/server.hpp>

	namespace phosphor
	{
	namespace led
	{
	/** @brief Assert LED by writing 255 */
	constexpr unsigned long ASSERT = 255;

	/** @brief De-assert by writing "0" */
	constexpr unsigned long DEASSERT = 0;

	/** @class Physical
	* @brief Responsible for applying actions on a particular physical LED
	*/
	class Physical : public sdbusplus::server::object::object<
	sdbusplus::xyz::openbmc_project::Led::server::Physical>
	{
	public:
	Physical() = delete;
	~Physical() = default;
	Physical(const Physical&) = delete;
	Physical& operator=(const Physical&) = delete;
	Physical(Physical&&) = delete;
	Physical& operator=(Physical&&) = delete;

	/** @brief Constructs LED object. Argument 'true' says that we hold off
	* from sending the signals since we need to do some house keeping and
	* only when we finish that, we are considered active and can then
	* broadcast the signal.
	*
	* @param[in] bus - system dbus handler
	* @param[in] objPath - The Dbus path that hosts physical LED
	* @param[in] ledPath - sysfs path where this LED is exported
	*/
	Physical(sdbusplus::bus::bus& bus, const std::string& objPath,
	SysfsLed& led) :

	sdbusplus::server::object::object<
	sdbusplus::xyz::openbmc_project::Led::server::Physical>(
	bus, objPath.c_str(), true),
	led(led)
	{
	// Suppose this is getting launched as part of BMC reboot, then we
	// need to save what the micro-controller currently has.
	setInitialState();

	// We are now ready.
	emit_object_added();
	}

	/** @brief Overloaded State Property Setter function
	*
	* @param[in] value - One of OFF / ON / BLINK
	* @return - Success or exception thrown
	*/
	Action state(Action value) override;

	private:
	/** @brief Associated LED implementation
	*/
	SysfsLed& led;

	/** @brief Frequency range that the LED can operate on.
	* Will be removed when frequency is put into interface
	*/
	uint32_t frequency;

	/** @brief reads sysfs and then setsup the parameteres accordingly
	*
	* @return None
	*/
	void setInitialState();

	/** @brief Applies the user triggered action on the LED
	* by writing to sysfs
	*
	* @param [in] current - Current state of LED
	* @param [in] request - Requested state
	*
	* @return None
	*/
	void driveLED(Action current, Action request);

	/** @brief Sets the LED to either ON or OFF state
	*
	* @param [in] action - Requested action. Could be OFF or ON
	* @return None
	*/
	void stableStateOperation(Action action);

	/** @brief Sets the LED to BLINKING
	*
	* @return None
	*/
	void blinkOperation();
	};

	} // namespace led
	} // namespace phosphor