include/ipmid/api.hpp - openbmc/phosphor-host-ipmid - Gitiles

 /*
  * Copyright © 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

 #define ALLOW_DEPRECATED_API 1

 #include <ipmid/iana.hpp>
 #include <ipmid/message/types.hpp>
 #include <optional>
 #include <sdbusplus/asio/connection.hpp>
 #include <sdbusplus/asio/object_server.hpp>

 /* NOTE:
  *
  * This is intended for native C++ use. For the legacy C api, include
  * ipmid-api.h for a reduced functionality. Note that the C api is now marked
  * as deprecated and will be removed once all the internal users of it have
  * been updated to use the new C++ api.
  */

 namespace ipmi
 {

 using Iana = oem::Number;

 using Group = uint8_t;
 constexpr Group groupPICMG = 0x00;
 constexpr Group groupDMTG = 0x01;
 constexpr Group groupSSI = 0x02;
 constexpr Group groupVSO = 0x03;
 constexpr Group groupDCMI = 0xDC;

 /*
  * Set the priority as the lowest number that is necessary so
  * it is possible that others can override it if desired.
  * This may be linked to what level of integration the handler
  * is being created at.
  */
 constexpr int prioOpenBmcBase = 10;
 constexpr int prioOemBase = 20;
 constexpr int prioOdmBase = 30;
 constexpr int prioCustomBase = 40;
 constexpr int prioMax = 50;

 /*
  * Channel IDs pulled from the IPMI 2.0 specification
  */
 constexpr int channelPrimaryIpmb = 0x00;
 // 0x01-0x0B Implementation specific
 // Implementation specific channel numbers are specified
 // by a configuration file external to ipmid
 // 0x0C-0x0D reserved
 constexpr int channelCurrentIface = 0x0E; // 'Present I/F'
 constexpr int channelSystemIface = 0x0F;

 /*
  * Specifies the minimum privilege level required to execute the command
  * This means the command can be executed at a given privilege level or higher
  * privilege level. Those commands which can be executed via system interface
  * only should use SYSTEM_INTERFACE
  */
 enum class Privilege : uint8_t
 {
     None = 0x00,
     Callback,
     User,
     Operator,
     Admin,
     Oem,
 };

 // IPMI Net Function number as specified by IPMI V2.0 spec.
 using NetFn = uint8_t;

 // IPMI Command for a Net Function number as specified by IPMI V2.0 spec.
 using Cmd = uint8_t;

 // ipmi function return the status code
 using Cc = uint8_t;

 // These are the command network functions, the response
 // network functions are the function + 1. So to determine
 // the proper network function which issued the command
 // associated with a response, subtract 1.
 // Note: these will be left shifted when combined with the LUN
 constexpr NetFn netFnChassis = 0x00;
 constexpr NetFn netFnBridge = 0x02;
 constexpr NetFn netFnSensor = 0x04;
 constexpr NetFn netFnApp = 0x06;
 constexpr NetFn netFnFirmware = 0x08;
 constexpr NetFn netFnStorage = 0x0A;
 constexpr NetFn netFnTransport = 0x0C;
 // reserved 0Eh..28h
 constexpr NetFn netFnGroup = 0x2C;
 constexpr NetFn netFnOem = 0x2E;
 constexpr NetFn netFnOemOne = 0x30;
 constexpr NetFn netFnOemTwo = 0x32;
 constexpr NetFn netFnOemThree = 0x34;
 constexpr NetFn netFnOemFour = 0x36;
 constexpr NetFn netFnOemFive = 0x38;
 constexpr NetFn netFnOemSix = 0x3A;
 constexpr NetFn netFnOemSeven = 0x3C;
 constexpr NetFn netFnOemEight = 0x3E;

 // IPMI commands for net functions. Callbacks using this should be careful to
 // parse arguments to the sub-functions and can take advantage of the built-in
 // message handling mechanism to create custom routing
 constexpr Cmd cmdWildcard = 0xFF;

 // IPMI standard completion codes specified by the IPMI V2.0 spec.
 //
 // This might have been an enum class, but that would make it hard for
 // OEM- and command-specific completion codes to be added elsewhere.
 //
 // Custom completion codes can be defined in individual modules for
 // command specific errors in the 0x80-0xBE range
 //
 // Alternately, OEM completion codes are in the 0x01-0x7E range
 constexpr Cc ccSuccess = 0x00;
 constexpr Cc ccBusy = 0xC0;
 constexpr Cc ccInvalidCommand = 0xC1;
 constexpr Cc ccInvalidCommandOnLun = 0xC2;
 constexpr Cc ccTimeout = 0xC2;
 constexpr Cc ccOutOfSpace = 0xC2;
 constexpr Cc ccInvalidReservationId = 0xC5;
 constexpr Cc ccReqDataTruncated = 0xC6;
 constexpr Cc ccReqDataLenInvalid = 0xC7;
 constexpr Cc ccReqDataLenExceeded = 0xC8;
 constexpr Cc ccParmOutOfRange = 0xC9;
 constexpr Cc ccRetBytesUnavailable = 0xCA;
 constexpr Cc ccSensorInvalid = 0xCB;
 constexpr Cc ccInvalidFieldRequest = 0xCC;
 constexpr Cc ccIllegalCommand = 0xCD;
 constexpr Cc ccResponseError = 0xCE;
 constexpr Cc ccDuplicateRequest = 0xCF;
 constexpr Cc ccCmdFailSdrMode = 0xD0;
 constexpr Cc ccCmdFailFwUpdMode = 0xD1;
 constexpr Cc ccCmdFailInitAgent = 0xD2;
 constexpr Cc ccDestinationUnavailable = 0xD3;
 constexpr Cc ccInsufficientPrivilege = 0xD4;
 constexpr Cc ccCommandNotAvailable = 0xD5;
 constexpr Cc ccCommandDisabled = 0xD6;
 constexpr Cc ccUnspecifiedError = 0xFF;

 /* ipmi often has two return types:
  * 1. Failure: CC is non-zero; no trailing data
  * 2. Success: CC is zero; trailing data (usually a fixed type)
  *
  * using ipmi::response(cc, ...), it will automatically always pack
  * the correct type for the response without having to explicitly type out all
  * the parameters that the function would return.
  *
  * To enable this feature, you just define the ipmi function as returning an
  * ipmi::RspType which has the optional trailing data built in, with your types
  * defined as parameters.
  */

 template <typename... RetTypes>
 using RspType = std::tuple<ipmi::Cc, std::optional<std::tuple<RetTypes...>>>;

 /**
  * @brief helper function to create an IPMI response tuple
  *
  * IPMI handlers all return a tuple with two parts: a completion code and an
  * optional tuple containing the rest of the data to return. This helper
  * function makes it easier by constructing that out of an arbitrary number of
  * arguments.
  *
  * @param cc - the completion code for the response
  * @param args... - the optional list of values to return
  *
  * @return a standard IPMI return type (as described above)
  */
 template <typename... Args>
 static inline auto response(ipmi::Cc cc, Args&&... args)
 {
     return std::make_tuple(cc, std::make_optional(std::make_tuple(args...)));
 }
 static inline auto response(ipmi::Cc cc)
 {
     return std::make_tuple(cc, std::nullopt);
 }

 /**
  * @brief helper function to create an IPMI success response tuple
  *
  * IPMI handlers all return a tuple with two parts: a completion code and an
  * optional tuple containing the rest of the data to return. This helper
  * function makes it easier by constructing that out of an arbitrary number of
  * arguments. Because it is a success response, this automatically packs
  * the completion code, without needing to explicitly pass it in.
  *
  * @param args... - the optional list of values to return
  *
  * @return a standard IPMI return type (as described above)
  */
 template <typename... Args>
 static inline auto responseSuccess(Args&&... args)
 {
     return std::make_tuple(ipmi::ccSuccess,
                            std::make_optional(std::make_tuple(args...)));
 }
 static inline auto responseSuccess()
 {
     return std::make_tuple(ipmi::ccSuccess, std::nullopt);
 }

 } // namespace ipmi

 // any client can interact with the main asio context
 std::shared_ptr<boost::asio::io_context> getIoContext();

 // any client can interact with the main sdbus
 std::shared_ptr<sdbusplus::asio::connection> getSdBus();

 /**
  * @brief post some work to the async exection queue
  *
  * The IPMI daemon runs an async exection queue; this allows any function to
  * pass in work to be executed in that context
  *
  * @tparam WorkFn - a function of type void(void)
  * @param work - the callback function to be executed
  */
 template <typename WorkFn>
 static inline void post_work(WorkFn work)
 {
     getIoContext()->post(std::forward<WorkFn>(work));
 }

 enum class SignalResponse : int
 {
     breakExecution,
     continueExecution,
 };

 /**
  * @brief add a signal handler
  *
  * This registers a handler to be called asynchronously via the execution
  * queue when the specified signal is received.
  *
  * Priority allows a signal handler to specify what order in the handler
  * chain it gets called. Lower priority numbers will cause the handler to
  * be executed later in the chain, while the highest priority numbers will cause
  * the handler to be executed first.
  *
  * In order to facilitate a chain of handlers, each handler in the chain will be
  * able to return breakExecution or continueExecution. Returning breakExecution
  * will break the chain and no further handlers will execute for that signal.
  * Returning continueExecution will allow lower-priority handlers to execute.
  *
  * By default, the main asio execution loop will register a low priority
  * (prioOpenBmcBase) handler for SIGINT and SIGTERM to cause the process to stop
  * on either of those signals. To prevent one of those signals from causing the
  * process to stop, simply register a higher priority handler that returns
  * breakExecution.
  *
  * @param int - priority of handler
  * @param int - signal number to wait for
  * @param handler - the callback function to be executed
  */
 void registerSignalHandler(int priority, int signalNumber,
                            const std::function<SignalResponse(int)>& handler);
	/*
	* Copyright © 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

	#define ALLOW_DEPRECATED_API 1

	#include <ipmid/iana.hpp>
	#include <ipmid/message/types.hpp>
	#include <optional>
	#include <sdbusplus/asio/connection.hpp>
	#include <sdbusplus/asio/object_server.hpp>

	/* NOTE:
	*
	* This is intended for native C++ use. For the legacy C api, include
	* ipmid-api.h for a reduced functionality. Note that the C api is now marked
	* as deprecated and will be removed once all the internal users of it have
	* been updated to use the new C++ api.
	*/

	namespace ipmi
	{

	using Iana = oem::Number;

	using Group = uint8_t;
	constexpr Group groupPICMG = 0x00;
	constexpr Group groupDMTG = 0x01;
	constexpr Group groupSSI = 0x02;
	constexpr Group groupVSO = 0x03;
	constexpr Group groupDCMI = 0xDC;

	/*
	* Set the priority as the lowest number that is necessary so
	* it is possible that others can override it if desired.
	* This may be linked to what level of integration the handler
	* is being created at.
	*/
	constexpr int prioOpenBmcBase = 10;
	constexpr int prioOemBase = 20;
	constexpr int prioOdmBase = 30;
	constexpr int prioCustomBase = 40;
	constexpr int prioMax = 50;

	/*
	* Channel IDs pulled from the IPMI 2.0 specification
	*/
	constexpr int channelPrimaryIpmb = 0x00;
	// 0x01-0x0B Implementation specific
	// Implementation specific channel numbers are specified
	// by a configuration file external to ipmid
	// 0x0C-0x0D reserved
	constexpr int channelCurrentIface = 0x0E; // 'Present I/F'
	constexpr int channelSystemIface = 0x0F;

	/*
	* Specifies the minimum privilege level required to execute the command
	* This means the command can be executed at a given privilege level or higher
	* privilege level. Those commands which can be executed via system interface
	* only should use SYSTEM_INTERFACE
	*/
	enum class Privilege : uint8_t
	{
	None = 0x00,
	Callback,
	User,
	Operator,
	Admin,
	Oem,
	};

	// IPMI Net Function number as specified by IPMI V2.0 spec.
	using NetFn = uint8_t;

	// IPMI Command for a Net Function number as specified by IPMI V2.0 spec.
	using Cmd = uint8_t;

	// ipmi function return the status code
	using Cc = uint8_t;

	// These are the command network functions, the response
	// network functions are the function + 1. So to determine
	// the proper network function which issued the command
	// associated with a response, subtract 1.
	// Note: these will be left shifted when combined with the LUN
	constexpr NetFn netFnChassis = 0x00;
	constexpr NetFn netFnBridge = 0x02;
	constexpr NetFn netFnSensor = 0x04;
	constexpr NetFn netFnApp = 0x06;
	constexpr NetFn netFnFirmware = 0x08;
	constexpr NetFn netFnStorage = 0x0A;
	constexpr NetFn netFnTransport = 0x0C;
	// reserved 0Eh..28h
	constexpr NetFn netFnGroup = 0x2C;
	constexpr NetFn netFnOem = 0x2E;
	constexpr NetFn netFnOemOne = 0x30;
	constexpr NetFn netFnOemTwo = 0x32;
	constexpr NetFn netFnOemThree = 0x34;
	constexpr NetFn netFnOemFour = 0x36;
	constexpr NetFn netFnOemFive = 0x38;
	constexpr NetFn netFnOemSix = 0x3A;
	constexpr NetFn netFnOemSeven = 0x3C;
	constexpr NetFn netFnOemEight = 0x3E;

	// IPMI commands for net functions. Callbacks using this should be careful to
	// parse arguments to the sub-functions and can take advantage of the built-in
	// message handling mechanism to create custom routing
	constexpr Cmd cmdWildcard = 0xFF;

	// IPMI standard completion codes specified by the IPMI V2.0 spec.
	//
	// This might have been an enum class, but that would make it hard for
	// OEM- and command-specific completion codes to be added elsewhere.
	//
	// Custom completion codes can be defined in individual modules for
	// command specific errors in the 0x80-0xBE range
	//
	// Alternately, OEM completion codes are in the 0x01-0x7E range
	constexpr Cc ccSuccess = 0x00;
	constexpr Cc ccBusy = 0xC0;
	constexpr Cc ccInvalidCommand = 0xC1;
	constexpr Cc ccInvalidCommandOnLun = 0xC2;
	constexpr Cc ccTimeout = 0xC2;
	constexpr Cc ccOutOfSpace = 0xC2;
	constexpr Cc ccInvalidReservationId = 0xC5;
	constexpr Cc ccReqDataTruncated = 0xC6;
	constexpr Cc ccReqDataLenInvalid = 0xC7;
	constexpr Cc ccReqDataLenExceeded = 0xC8;
	constexpr Cc ccParmOutOfRange = 0xC9;
	constexpr Cc ccRetBytesUnavailable = 0xCA;
	constexpr Cc ccSensorInvalid = 0xCB;
	constexpr Cc ccInvalidFieldRequest = 0xCC;
	constexpr Cc ccIllegalCommand = 0xCD;
	constexpr Cc ccResponseError = 0xCE;
	constexpr Cc ccDuplicateRequest = 0xCF;
	constexpr Cc ccCmdFailSdrMode = 0xD0;
	constexpr Cc ccCmdFailFwUpdMode = 0xD1;
	constexpr Cc ccCmdFailInitAgent = 0xD2;
	constexpr Cc ccDestinationUnavailable = 0xD3;
	constexpr Cc ccInsufficientPrivilege = 0xD4;
	constexpr Cc ccCommandNotAvailable = 0xD5;
	constexpr Cc ccCommandDisabled = 0xD6;
	constexpr Cc ccUnspecifiedError = 0xFF;

	/* ipmi often has two return types:
	* 1. Failure: CC is non-zero; no trailing data
	* 2. Success: CC is zero; trailing data (usually a fixed type)
	*
	* using ipmi::response(cc, ...), it will automatically always pack
	* the correct type for the response without having to explicitly type out all
	* the parameters that the function would return.
	*
	* To enable this feature, you just define the ipmi function as returning an
	* ipmi::RspType which has the optional trailing data built in, with your types
	* defined as parameters.
	*/

	template <typename... RetTypes>
	using RspType = std::tuple<ipmi::Cc, std::optional<std::tuple<RetTypes...>>>;

	/**
	* @brief helper function to create an IPMI response tuple
	*
	* IPMI handlers all return a tuple with two parts: a completion code and an
	* optional tuple containing the rest of the data to return. This helper
	* function makes it easier by constructing that out of an arbitrary number of
	* arguments.
	*
	* @param cc - the completion code for the response
	* @param args... - the optional list of values to return
	*
	* @return a standard IPMI return type (as described above)
	*/
	template <typename... Args>
	static inline auto response(ipmi::Cc cc, Args&&... args)
	{
	return std::make_tuple(cc, std::make_optional(std::make_tuple(args...)));
	}
	static inline auto response(ipmi::Cc cc)
	{
	return std::make_tuple(cc, std::nullopt);
	}

	/**
	* @brief helper function to create an IPMI success response tuple
	*
	* IPMI handlers all return a tuple with two parts: a completion code and an
	* optional tuple containing the rest of the data to return. This helper
	* function makes it easier by constructing that out of an arbitrary number of
	* arguments. Because it is a success response, this automatically packs
	* the completion code, without needing to explicitly pass it in.
	*
	* @param args... - the optional list of values to return
	*
	* @return a standard IPMI return type (as described above)
	*/
	template <typename... Args>
	static inline auto responseSuccess(Args&&... args)
	{
	return std::make_tuple(ipmi::ccSuccess,
	std::make_optional(std::make_tuple(args...)));
	}
	static inline auto responseSuccess()
	{
	return std::make_tuple(ipmi::ccSuccess, std::nullopt);
	}

	} // namespace ipmi

	// any client can interact with the main asio context
	std::shared_ptr<boost::asio::io_context> getIoContext();

	// any client can interact with the main sdbus
	std::shared_ptr<sdbusplus::asio::connection> getSdBus();

	/**
	* @brief post some work to the async exection queue
	*
	* The IPMI daemon runs an async exection queue; this allows any function to
	* pass in work to be executed in that context
	*
	* @tparam WorkFn - a function of type void(void)
	* @param work - the callback function to be executed
	*/
	template <typename WorkFn>
	static inline void post_work(WorkFn work)
	{
	getIoContext()->post(std::forward<WorkFn>(work));
	}

	enum class SignalResponse : int
	{
	breakExecution,
	continueExecution,
	};

	/**
	* @brief add a signal handler
	*
	* This registers a handler to be called asynchronously via the execution
	* queue when the specified signal is received.
	*
	* Priority allows a signal handler to specify what order in the handler
	* chain it gets called. Lower priority numbers will cause the handler to
	* be executed later in the chain, while the highest priority numbers will cause
	* the handler to be executed first.
	*
	* In order to facilitate a chain of handlers, each handler in the chain will be
	* able to return breakExecution or continueExecution. Returning breakExecution
	* will break the chain and no further handlers will execute for that signal.
	* Returning continueExecution will allow lower-priority handlers to execute.
	*
	* By default, the main asio execution loop will register a low priority
	* (prioOpenBmcBase) handler for SIGINT and SIGTERM to cause the process to stop
	* on either of those signals. To prevent one of those signals from causing the
	* process to stop, simply register a higher priority handler that returns
	* breakExecution.
	*
	* @param int - priority of handler
	* @param int - signal number to wait for
	* @param handler - the callback function to be executed
	*/
	void registerSignalHandler(int priority, int signalNumber,
	const std::function<SignalResponse(int)>& handler);