IPMI is made up of commands and channels. Commands are provided by providers and channels are processes called bridges. Commands are received from external sources (system admin users) via the bridges and routed to the providers' command handlers via the main IPMI daemon.
IPMI is all about commands and responses. Channels provide a mechanism for transporting the data, each with a slightly different protocol and transport layer, but ultimately, the highest level data is a raw IPMI command consisting of a NetFn/LUN, Command, and optional data. Each response is likewise a Completion Code and optional data. So the first step is to break apart channels and the IPMI queue.
/------------------\ /----------------------------\ | | | KCS/BT - Host | <-All IPMI cmds-> | | | | | | \----------------------------/ | IPMI Daemon | | (ipmid) | | | /-----------------------------\ | | | LAN - RMCP+ | | | | /--------------------------\| | | | |*Process the Session and || <-All IPMI cmds-> | | | | SOL commands. || except session | | | |*Create Session Objs || and SOL cmds | | | \--------------------------/| | | \-----------------------------/ \------------------/ : ^ ^ : | | : | | /-------------------------\ | | | Active session/SOL Objs | <---------Query the session-/ | | - Properities | and SOL data via Dbus | \-------------------------/ | V ---------------------\ | D-Bus services | | ------------------ | | Do work on behalf | | of IPMI commands | ---------------------/
The IPMI messages that get passed to and from the IPMI daemon (ipmid) are basically the equivalent of ipmitool's "raw" commands with a little more information about the message.
Message Data: byte:LUN - LUN from netFn/LUN pair (0-3, as per the IPMI spec) byte:netFn - netFn from netFn/LUN pair (as per the IPMI spec) byte:cmd - IPMI command ID (as per the IPMI spec) array<byte>:data - optional command data (as per the IPMI spec) dict<string:variant>:options - optional additional meta-data "userId":int - IPMI user ID of caller (0 for session-less channels) "privilege": enum:privilege - ADMIN, USER, OPERATOR, CALLBACK; must be less than or equal to the privilege of the user and less than or equal to the max privilege of this channel
Response Data: byte:CC - IPMI completion code array<byte>:data - optional response data
A channel bridge, upon receiving a new IPMI command, will extract the necessary fields from whatever transport format (RMCP+, IPMB, KCS, etc.) For session-based channels (RMCP+) the bridge is responsible for establishing the session with credentials and determining the maximum privilege available for this session. The bridge then takes the extracted command, data, and possibly user and privilge information, and encodes them in a D-Bus method call to send to the IPMI daemon, ipmid. The daemon will take the message, and attempt to find an appropriate handler in its handler tables. If a handler is found, it will attempt to extract the required parameters for the handler and pass them along. The handler will return a tuple of response parameters, which will get packed back into a D-Bus response message and sent back to the calling channel's bridge. The bridge will then re-package the response into its transport protocol and send it off.
The next part is to provide a higher-level, strongly-typed, modern C++ mechanism for registering handlers. Each handler will specify exactly what arguments are needed for the command and what types will be returned in the response. This way, the ipmid queue can unpack requests and pack responses in a safe manner. Because the handler packing and unpacking code is templated, it is written mostly in headers.
For session-less channels (like BT, KCS, and IPMB), the only privilege check will be to see that the requested privilege is less than or equal to the channel's maximum privilege. If the channel has a session and authenticates users, the privilege must be less than or equal to the channel's maximum privilege and the user's maximum privilege.
Ipmid takes the LUN/netFN/Cmd tuple and looks up the corresponding handler function. If the requested privilege is less than or equal to the required privilege for the given registered command, the request may proceed. If any of these checks fail, ipmid returns with Insufficient Privilege.
At this point, the IPMI command is run through the filter hooks. The default hook is ACCEPT, where the command just passes onto the execution phase. But OEMs and providers can register hooks that would ultimately block IPMI commands from executing, much like the IPMI 2.0 Spec's Firmware Firewall. The hook would be passed in the context of the IPMI call and the raw content of the call and has the opportunity to return any valid IPMI completion code. Any non-zero completion code would prevent the command from executing and would be returned to the caller.
The network channel bridges (netipmid), executing one process per interface, handle session (RMCP+) and SOL commands and responses to those commands. Get/Set SOL configuration, Get session info, close session commands can also be requested through KCS/BT interface, ipmid daemon must also need details about session and SOL. In order to maintain sync between ipmid and netipmid daemon, session and SOL are exposed in D-Bus, which ipmid can query and respond to commands issued through host interface (KCS/BT).
The next phase is parameter unpacking and validation. This is done by compiler-generated code with variadic templates at handler registration time. The registration function is a templated function that allows any type of handler to be passed in so that the types of the handler can be extracted and unpacked.
This is done in the core IPMI library (from a high level) like this:
template <typename Handler> class IpmiHandler { public: explicit IpmiHandler(Handler&& handler) : handler_(std::forward<Handler>(handler)) { } message::Response::ptr call(message::Request::ptr request) { message::Response::ptr response = request->makeResponse(); // < code to deduce UnpackArgsType and ResultType from Handler > UnpackArgsType unpackArgs; ipmi::Cc unpackError = request->unpack(unpackArgs); if (unpackError != ipmi::ccSuccess) { response->cc = unpackError; return response; } ResultType result = std::apply(handler_, unpackArgs); response->cc = std::get<0>(result); auto payload = std::get<1>(result); response->pack(*payload); return response; } private: Handler handler_; }; ... namespace ipmi { constexpr NetFn netFnApp = 0x06; namespace app { constexpr Cmd cmdSetUserAccessCommand = 0x43; } class Context { NetFn netFn; Cmd cmd; int channel; int userId; Privilege priv; boost::asio::yield_context* yield; // for async operations }; }
While some IPMI handlers would look like this:
ipmi::RspType<> setUserAccess( std::shared_ptr<ipmi::Context> context, uint4_t channelNumber, bool ipmiEnable, bool linkAuth, bool callbackRestricted, bool changeBit, uint6_t userId, uint2_t reserved1, uint4_t privLimit, uint4_t reserved2, std::optional<uint4_t> userSessionLimit, std::optional<uint4_t> reserved3) { ... return ipmi::ResponseSuccess(); } ipmi::RspType<uint8_t, // max user IDs uint6_t, // count of enabled user IDs uint2_t, // user ID enable status uint8_t, // count of fixed user IDs uint4_t // user privilege for given channel bool, // ipmi messaging enabled bool, // link authentication enabled bool, // callback access bool, // reserved bit > getUserAccess(std::shared_ptr<ipmi::Context> context, uint8_t channelNumber, uint8_t userId) { if (<some error condition>) { return ipmi::response(ipmi::ccParmOutOfRange); } // code to get const auto& [usersMax, status, usersEnabled, usersFixed, access, priv] = getSdBus()->yield_method_call(*context->yield, ...); return ipmi::responseSuccess(usersMax, usersEnabled, status, usersFixed, priv, access.messaging, access.linkAuth, access.callback, false); } void providerInitFn() { ipmi::registerHandler(ipmi::prioOpenBmcBase, ipmi::netFnApp, ipmi::app::cmdSetUserAccessCommand, ipmi::Privilege::Admin, setUserAccess); ipmi::registerHandler(ipmi::prioOpenBmcBase, ipmi::netFnApp, ipmi::app::cmdGetUserAccessCommand, ipmi::Privilege::Operator, getUserAccess); }
Ipmid providers are all executed as boost::asio::coroutines. This means that they can take advantage of any of the boost::asio async method calls in a way that looks like synchronous code, but will execute asynchronously by yielding control of the processor to the run loop via the yield_context object. Use the yield_context object by passing it as a 'callback' which will then cause the calling coroutine to yield the processor until its IO is ready, at which point it will 'return' much like a synchronous call.
Ideally, all handlers would take advantage of the asynchronous capabilities of ipmid via the boost::asio::yield_context. This means that the queue could have multiple in-flight calls that are waiting on another D-Bus call to return. With asynchronous calls, this will not block the rest of the queue's operation, The sdbusplus::asio::connection that is available to all providers via the getSdBus() function provides yield_method_call() which is an asynchronous D-Bus call mechanism that 'looks' like a synchronous call. It is important that any global data that an asynchronous handler uses is protected as if the handler is multi-threaded. Since many of the resources used in IPMI handlers are actually D-Bus objects, this is not likely a common issue because of the serialization that happens via the D-Bus calls.
Using templates, it is possible to extract the return type and argument types of the handlers and use that to unpack (and validate) the arguments from the incoming request and then pack the result back into a vector of bytes to send back to the caller. The deserializer will keep track of the number of bits it has unpacked and then compare it with the total number of bits that the method is requesting. In the example, we are assuming that the non-full-byte integers are packed bits in the message in most-significant-bit first order (same order the specification describes them in). Optional arguments can be used easily with C++17's std::optional.
Some types that are supported are as follows:
For partial byte types, the least-significant bits of the next full byte are extracted first. While this is opposite of the order the IPMI specification is written, it makes the code simple. Multi-byte fields are extracted as LSByte first (little-endian) to match the IPMI specification.
When returning partial byte types, they are also packed into the reply in the least-significant bit first order. As each byte fills up, the full byte gets pushed onto the byte stream. For examples of how the packing and unpacking is used, see the unit test cases in test/message/pack.cpp and test/message/unpack.cpp.
As an example this is how a bitset is unpacked
/** @brief Specialization of UnpackSingle for std::bitset<N> */ template <size_t N> struct UnpackSingle<std::bitset<N>> { static int op(Payload& p, std::bitset<N>& t) { static_assert(N <= (details::bitStreamSize - CHAR_BIT)); size_t count = N; // acquire enough bits in the stream to fulfill the Payload if (p.fillBits(count)) { return -1; } fixed_uint_t<details::bitStreamSize> bitmask = ((1 << count) - 1); t |= (p.bitStream & bitmask).convert_to<unsigned long long>(); p.bitStream >>= count; p.bitCount -= count; return 0; } };
If a handler needs to unpack a variable payload, it is possible to request the Payload parameter. When the Payload parameter is present, any remaining, unpacked bytes are available for inspection. Using the same unpacking calls that were used to unpack the other parameters, the remaining parameters can be manually unpacked. This is helpful for multi-function commands like Set LAN Configuration Parameters, where the first two bytes are fixed, but the remaining 3:N bytes vary based on the selected parameter.