ipmid.cpp - openbmc/phosphor-host-ipmid - Gitiles

 #include "config.h"

 #include "ipmid.hpp"

 #include "host-cmd-manager.hpp"
 #include "ipmiwhitelist.hpp"
 #include "sensorhandler.hpp"
 #include "settings.hpp"

 #include <assert.h>
 #include <dirent.h>
 #include <dlfcn.h>
 #include <errno.h>
 #include <sys/time.h>
 #include <systemd/sd-bus.h>
 #include <unistd.h>

 #include <algorithm>
 #include <cstring>
 #include <host-ipmid/ipmid-host-cmd.hpp>
 #include <host-ipmid/oemrouter.hpp>
 #include <iostream>
 #include <iterator>
 #include <map>
 #include <memory>
 #include <phosphor-logging/log.hpp>
 #include <sdbusplus/bus.hpp>
 #include <sdbusplus/bus/match.hpp>
 #include <sdbusplus/message/types.hpp>
 #include <sdbusplus/timer.hpp>
 #include <vector>
 #include <xyz/openbmc_project/Control/Security/RestrictionMode/server.hpp>

 using namespace phosphor::logging;
 namespace sdbusRule = sdbusplus::bus::match::rules;
 namespace variant_ns = sdbusplus::message::variant_ns;

 sd_bus* bus = NULL;
 sd_bus_slot* ipmid_slot = NULL;
 sd_event* events = nullptr;

 // Need this to use new sdbusplus compatible interfaces
 sdbusPtr sdbusp;

 // Global Host Bound Command manager
 using cmdManagerPtr = std::unique_ptr<phosphor::host::command::Manager>;
 cmdManagerPtr cmdManager;

 // Global timer for network changes
 std::unique_ptr<phosphor::Timer> networkTimer = nullptr;

 // Command and handler tuple. Used when clients ask the command to be put
 // into host message queue
 using CommandHandler = phosphor::host::command::CommandHandler;

 // Initialise restricted mode to true
 bool restricted_mode = true;

 FILE *ipmiio, *ipmidbus, *ipmicmddetails;

 void print_usage(void)
 {
     std::fprintf(stderr, "Options:  [-d mask]\n");
     std::fprintf(stderr, "    mask : 0x01 - Print ipmi packets\n");
     std::fprintf(stderr, "    mask : 0x02 - Print DBUS operations\n");
     std::fprintf(stderr, "    mask : 0x04 - Print ipmi command details\n");
     std::fprintf(stderr, "    mask : 0xFF - Print all trace\n");
 }

 const char* DBUS_INTF = "org.openbmc.HostIpmi";

 const char* FILTER =
     "type='signal',interface='org.openbmc.HostIpmi',member='ReceivedMessage'";

 typedef std::pair<ipmi_netfn_t, ipmi_cmd_t> ipmi_fn_cmd_t;
 typedef std::pair<ipmid_callback_t, ipmi_context_t> ipmi_fn_context_t;

 // Global data structure that contains the IPMI command handler's registrations.
 std::map<ipmi_fn_cmd_t, ipmi_fn_context_t> g_ipmid_router_map;

 // IPMI Spec, shared Reservation ID.
 static unsigned short selReservationID = 0xFFFF;
 static bool selReservationValid = false;

 unsigned short reserveSel(void)
 {
     // IPMI spec, Reservation ID, the value simply increases against each
     // execution of the Reserve SEL command.
     if (++selReservationID == 0)
     {
         selReservationID = 1;
     }
     selReservationValid = true;
     return selReservationID;
 }

 bool checkSELReservation(unsigned short id)
 {
     return (selReservationValid && selReservationID == id);
 }

 void cancelSELReservation(void)
 {
     selReservationValid = false;
 }

 namespace internal
 {

 constexpr auto restrictionModeIntf =
     "xyz.openbmc_project.Control.Security.RestrictionMode";

 namespace cache
 {

 std::unique_ptr<settings::Objects> objects = nullptr;

 } // namespace cache
 } // namespace internal

 #ifndef HEXDUMP_COLS
 #define HEXDUMP_COLS 16
 #endif

 void hexdump(FILE* s, void* mem, size_t len)
 {
     unsigned int i, j;

     for (i = 0;
          i <
          len + ((len % HEXDUMP_COLS) ? (HEXDUMP_COLS - len % HEXDUMP_COLS) : 0);
          i++)
     {
         /* print offset */
         if (i % HEXDUMP_COLS == 0)
         {
             std::fprintf(s, "0x%06x: ", i);
         }

         /* print hex data */
         if (i < len)
         {
             std::fprintf(s, "%02x ", 0xFF & ((char*)mem)[i]);
         }
         else /* end of block, just aligning for ASCII dump */
         {
             std::fprintf(s, "   ");
         }

         /* print ASCII dump */
         if (i % HEXDUMP_COLS == (HEXDUMP_COLS - 1))
         {
             for (j = i - (HEXDUMP_COLS - 1); j <= i; j++)
             {
                 if (j >= len) /* end of block, not really printing */
                 {
                     std::fputc(' ', s);
                 }
                 else if (std::isprint(((char*)mem)[j])) /* printable char */
                 {
                     std::fputc(0xFF & ((char*)mem)[j], s);
                 }
                 else /* other char */
                 {
                     std::fputc('.', s);
                 }
             }
             std::fputc('\n', s);
         }
     }
 }

 // Method that gets called by shared libraries to get their command handlers
 // registered
 void ipmi_register_callback(ipmi_netfn_t netfn, ipmi_cmd_t cmd,
                             ipmi_context_t context, ipmid_callback_t handler,
                             ipmi_cmd_privilege_t priv)
 {
     // Pack NetFn and Command in one.
     auto netfn_and_cmd = std::make_pair(netfn, cmd);

     // Pack Function handler and Data in another.
     auto handler_and_context = std::make_pair(handler, context);

     // Check if the registration has already been made..
     auto iter = g_ipmid_router_map.find(netfn_and_cmd);
     if (iter != g_ipmid_router_map.end())
     {
         log<level::ERR>("Duplicate registration", entry("NETFN=0x%X", netfn),
                         entry("CMD=0x%X", cmd));
     }
     else
     {
         // This is a fresh registration.. Add it to the map.
         g_ipmid_router_map.emplace(netfn_and_cmd, handler_and_context);
     }

     return;
 }

 // Looks at the map and calls corresponding handler functions.
 ipmi_ret_t ipmi_netfn_router(ipmi_netfn_t netfn, ipmi_cmd_t cmd,
                              ipmi_request_t request, ipmi_response_t response,
                              ipmi_data_len_t data_len)
 {
     // return from the Command handlers.
     ipmi_ret_t rc = IPMI_CC_INVALID;

     // If restricted mode is true and command is not whitelisted, don't
     // execute the command
     if (restricted_mode)
     {
         if (!std::binary_search(whitelist.cbegin(), whitelist.cend(),
                                 std::make_pair(netfn, cmd)))
         {
             log<level::ERR>("Net function not whitelisted",
                             entry("NETFN=0x%X", netfn), entry("CMD=0x%X", cmd));
             rc = IPMI_CC_INSUFFICIENT_PRIVILEGE;
             std::memcpy(response, &rc, IPMI_CC_LEN);
             *data_len = IPMI_CC_LEN;
             return rc;
         }
     }

     // Walk the map that has the registered handlers and invoke the approprite
     // handlers for matching commands.
     auto iter = g_ipmid_router_map.find(std::make_pair(netfn, cmd));
     if (iter == g_ipmid_router_map.end())
     {
         /* By default should only print on failure to find wildcard command. */
 #ifdef __IPMI_DEBUG__
         log<level::ERR>(
             "No registered handlers for NetFn, trying Wilcard implementation",
             entry("NET_FUN=0x%X", netfn) entry("CMD=0x%X", IPMI_CMD_WILDCARD));
 #endif

         // Now that we did not find any specific [NetFn,Cmd], tuple, check for
         // NetFn, WildCard command present.
         iter =
             g_ipmid_router_map.find(std::make_pair(netfn, IPMI_CMD_WILDCARD));
         if (iter == g_ipmid_router_map.end())
         {
             log<level::ERR>("No Registered handlers for NetFn",
                             entry("NET_FUN=0x%X", netfn),
                             entry("CMD=0x%X", IPMI_CMD_WILDCARD));

             // Respond with a 0xC1
             std::memcpy(response, &rc, IPMI_CC_LEN);
             *data_len = IPMI_CC_LEN;
             return rc;
         }
     }

 #ifdef __IPMI_DEBUG__
     // We have either a perfect match -OR- a wild card atleast,
     log<level::ERR>("Calling Net function",
                     entry("NET_FUN=0x%X", netfn) entry("CMD=0x%X", cmd));
 #endif

     // Extract the map data onto appropriate containers
     auto handler_and_context = iter->second;

     // Creating a pointer type casted to char* to make sure we advance 1 byte
     // when we advance pointer to next's address. advancing void * would not
     // make sense.
     char* respo = &((char*)response)[IPMI_CC_LEN];

     try
     {
         // Response message from the plugin goes into a byte post the base
         // response
         rc = (handler_and_context.first)(netfn, cmd, request, respo, data_len,
                                          handler_and_context.second);
     }
     // IPMI command handlers can throw unhandled exceptions, catch those
     // and return sane error code.
     catch (const std::exception& e)
     {
         log<level::ERR>(e.what(), entry("NET_FUN=0x%X", netfn),
                         entry("CMD=0x%X", cmd));
         rc = IPMI_CC_UNSPECIFIED_ERROR;
         *data_len = 0;
         // fall through
     }
     // Now copy the return code that we got from handler and pack it in first
     // byte.
     std::memcpy(response, &rc, IPMI_CC_LEN);

     // Data length is now actual data + completion code.
     *data_len = *data_len + IPMI_CC_LEN;

     return rc;
 }

 static int send_ipmi_message(sd_bus_message* req, unsigned char seq,
                              unsigned char netfn, unsigned char lun,
                              unsigned char cmd, unsigned char cc,
                              unsigned char* buf, unsigned char len)
 {

     sd_bus_error error = SD_BUS_ERROR_NULL;
     sd_bus_message *reply = NULL, *m = NULL;
     const char *dest, *path;
     int r, pty;

     dest = sd_bus_message_get_sender(req);
     path = sd_bus_message_get_path(req);

     r = sd_bus_message_new_method_call(bus, &m, dest, path, DBUS_INTF,
                                        "sendMessage");
     if (r < 0)
     {
         log<level::ERR>("Failed to add the method object",
                         entry("ERRNO=0x%X", -r));
         return -1;
     }

     // Responses in IPMI require a bit set.  So there ya go...
     netfn |= 0x01;

     // Add the bytes needed for the methods to be called
     r = sd_bus_message_append(m, "yyyyy", seq, netfn, lun, cmd, cc);
     if (r < 0)
     {
         log<level::ERR>("Failed add the netfn and others",
                         entry("ERRNO=0x%X", -r));
         goto final;
     }

     r = sd_bus_message_append_array(m, 'y', buf, len);
     if (r < 0)
     {
         log<level::ERR>("Failed to add the string of response bytes",
                         entry("ERRNO=0x%X", -r));
         goto final;
     }

     // Call the IPMI responder on the bus so the message can be sent to the CEC
     r = sd_bus_call(bus, m, 0, &error, &reply);
     if (r < 0)
     {
         log<level::ERR>("Failed to call the method", entry("DEST=%s", dest),
                         entry("PATH=%s", path), entry("ERRNO=0x%X", -r));
         goto final;
     }

     r = sd_bus_message_read(reply, "x", &pty);
     if (r < 0)
     {
         log<level::ERR>("Failed to get a reply from the method",
                         entry("ERRNO=0x%X", -r));
     }

 final:
     sd_bus_error_free(&error);
     m = sd_bus_message_unref(m);
     reply = sd_bus_message_unref(reply);

     return r < 0 ? EXIT_FAILURE : EXIT_SUCCESS;
 }

 void cache_restricted_mode()
 {
     restricted_mode = false;
     using namespace sdbusplus::xyz::openbmc_project::Control::Security::server;
     using namespace internal;
     using namespace internal::cache;
     sdbusplus::bus::bus dbus(ipmid_get_sd_bus_connection());
     const auto& restrictionModeSetting =
         objects->map.at(restrictionModeIntf).front();
     auto method = dbus.new_method_call(
         objects->service(restrictionModeSetting, restrictionModeIntf).c_str(),
         restrictionModeSetting.c_str(), "org.freedesktop.DBus.Properties",
         "Get");
     method.append(restrictionModeIntf, "RestrictionMode");
     auto resp = dbus.call(method);
     if (resp.is_method_error())
     {
         log<level::ERR>("Error in RestrictionMode Get");
         // Fail-safe to true.
         restricted_mode = true;
         return;
     }
     sdbusplus::message::variant<std::string> result;
     resp.read(result);
     auto restrictionMode = RestrictionMode::convertModesFromString(
         variant_ns::get<std::string>(result));
     if (RestrictionMode::Modes::Whitelist == restrictionMode)
     {
         restricted_mode = true;
     }
 }

 static int handle_restricted_mode_change(sd_bus_message* m, void* user_data,
                                          sd_bus_error* ret_error)
 {
     cache_restricted_mode();
     return 0;
 }

 static int handle_ipmi_command(sd_bus_message* m, void* user_data,
                                sd_bus_error* ret_error)
 {
     int r = 0;
     unsigned char sequence, netfn, lun, cmd;
     const void* request;
     size_t sz;
     size_t resplen = MAX_IPMI_BUFFER;
     unsigned char response[MAX_IPMI_BUFFER];

     std::memset(response, 0, MAX_IPMI_BUFFER);

     r = sd_bus_message_read(m, "yyyy", &sequence, &netfn, &lun, &cmd);
     if (r < 0)
     {
         log<level::ERR>("Failed to parse signal message",
                         entry("ERRNO=0x%X", -r));
         return -1;
     }

     r = sd_bus_message_read_array(m, 'y', &request, &sz);
     if (r < 0)
     {
         log<level::ERR>("Failed to parse signal message",
                         entry("ERRNO=0x%X", -r));
         return -1;
     }

     std::fprintf(ipmiio,
                  "IPMI Incoming: Seq 0x%02x, NetFn 0x%02x, CMD: 0x%02x \n",
                  sequence, netfn, cmd);
     hexdump(ipmiio, (void*)request, sz);

     // Allow the length field to be used for both input and output of the
     // ipmi call
     resplen = sz;

     // Now that we have parsed the entire byte array from the caller
     // we can call the ipmi router to do the work...
     r = ipmi_netfn_router(netfn, cmd, (void*)request, (void*)response,
                           &resplen);
     if (r != 0)
     {
 #ifdef __IPMI_DEBUG__
         log<level::ERR>("ERROR in handling NetFn", entry("ERRNO=0x%X", -r),
                         entry("NET_FUN=0x%X", netfn), entry("CMD=0x%X", cmd));
 #endif
         resplen = 0;
     }
     else
     {
         resplen = resplen - 1; // first byte is for return code.
     }

     std::fprintf(ipmiio, "IPMI Response:\n");
     hexdump(ipmiio, (void*)response, resplen);

     // Send the response buffer from the ipmi command
     r = send_ipmi_message(m, sequence, netfn, lun, cmd, response[0],
                           ((unsigned char*)response) + 1, resplen);
     if (r < 0)
     {
         log<level::ERR>("Failed to send the response message");
         return -1;
     }

     return 0;
 }

 //----------------------------------------------------------------------
 // handler_select
 // Select all the files ending with with .so. in the given diretcory
 // @d: dirent structure containing the file name
 //----------------------------------------------------------------------
 int handler_select(const struct dirent* entry)
 {
     // To hold ".so" from entry->d_name;
     char dname_copy[4] = {0};

     // We want to avoid checking for everything and isolate to the ones having
     // .so.* or .so in them.
     // Check for versioned libraries .so.*
     if (strstr(entry->d_name, IPMI_PLUGIN_SONAME_EXTN))
     {
         return 1;
     }
     // Check for non versioned libraries .so
     else if (strstr(entry->d_name, IPMI_PLUGIN_EXTN))
     {
         // It is possible that .so could be anywhere in the string but unlikely
         // But being careful here. Get the base address of the string, move
         // until end and come back 3 steps and that gets what we need.
         strcpy(dname_copy, (entry->d_name + strlen(entry->d_name) -
                             strlen(IPMI_PLUGIN_EXTN)));
         if (strcmp(dname_copy, IPMI_PLUGIN_EXTN) == 0)
         {
             return 1;
         }
     }
     return 0;
 }

 // This will do a dlopen of every .so in ipmi_lib_path and will dlopen
 // everything so that they will register a callback handler
 void ipmi_register_callback_handlers(const char* ipmi_lib_path)
 {
     // For walking the ipmi_lib_path
     struct dirent** handler_list;

     // This is used to check and abort if someone tries to register a bad one.
     void* lib_handler = NULL;

     if (ipmi_lib_path == NULL)
     {
         log<level::ERR>("No handlers to be registered for ipmi.. Aborting");
         assert(0);
     }
     else
     {
         // 1: Open ipmi_lib_path. Its usually "/usr/lib/phosphor-host-ipmid"
         // 2: Scan the directory for the files that end with .so
         // 3: For each one of them, just do a 'dlopen' so that they register
         //    the handlers for callback routines.

         std::string handler_fqdn = ipmi_lib_path;

         // Append a "/" since we need to add the name of the .so. If there is
         // already a .so, adding one more is not any harm.
         handler_fqdn += "/";

         int num_handlers =
             scandir(ipmi_lib_path, &handler_list, handler_select, alphasort);
         if (num_handlers < 0)
             return;

         while (num_handlers--)
         {
             handler_fqdn = ipmi_lib_path;
             handler_fqdn += handler_list[num_handlers]->d_name;
 #ifdef __IPMI_DEBUG__
             log<level::DEBUG>("Registering handler",
                               entry("HANDLER=%s", handler_fqdn.c_str()));
 #endif

             lib_handler = dlopen(handler_fqdn.c_str(), RTLD_NOW);

             if (lib_handler == NULL)
             {
                 log<level::ERR>("ERROR opening",
                                 entry("HANDLER=%s", handler_fqdn.c_str()),
                                 entry("ERROR=%s", dlerror()));
             }
             // Wipe the memory allocated for this particular entry.
             free(handler_list[num_handlers]);
         }

         // Done with all registration.
         free(handler_list);
     }

     // TODO : What to be done on the memory that is given by dlopen ?.
     return;
 }

 sd_bus* ipmid_get_sd_bus_connection(void)
 {
     return bus;
 }

 sd_event* ipmid_get_sd_event_connection(void)
 {
     return events;
 }

 sd_bus_slot* ipmid_get_sd_bus_slot(void)
 {
     return ipmid_slot;
 }

 EInterfaceIndex getInterfaceIndex(void)
 {
     return interfaceKCS;
 }

 // Calls host command manager to do the right thing for the command
 void ipmid_send_cmd_to_host(CommandHandler&& cmd)
 {
     return cmdManager->execute(std::move(cmd));
 }

 cmdManagerPtr& ipmid_get_host_cmd_manager()
 {
     return cmdManager;
 }

 sdbusPtr& ipmid_get_sdbus_plus_handler()
 {
     return sdbusp;
 }

 int main(int argc, char* argv[])
 {
     int r;
     unsigned long tvalue;
     int c;

     // This file and subsequient switch is for turning on levels
     // of trace
     ipmicmddetails = ipmiio = ipmidbus = fopen("/dev/null", "w");

     while ((c = getopt(argc, argv, "h:d:")) != -1)
         switch (c)
         {
             case 'd':
                 tvalue = strtoul(optarg, NULL, 16);
                 if (1 & tvalue)
                 {
                     ipmiio = stdout;
                 }
                 if (2 & tvalue)
                 {
                     ipmidbus = stdout;
                 }
                 if (4 & tvalue)
                 {
                     ipmicmddetails = stdout;
                 }
                 break;
             case 'h':
             case '?':
                 print_usage();
                 return 1;
         }

     /* Connect to system bus */
     r = sd_bus_default_system(&bus);
     if (r < 0)
     {
         log<level::ERR>("Failed to connect to system bus",
                         entry("ERRNO=0x%X", -r));
         goto finish;
     }

     /* Get an sd event handler */
     r = sd_event_default(&events);
     if (r < 0)
     {
         log<level::ERR>("Failure to create sd_event handler",
                         entry("ERRNO=0x%X", -r));
         goto finish;
     }

     // Now create the Host Bound Command manager. Need sdbusplus
     // to use the generated bindings
     sdbusp = std::make_unique<sdbusplus::bus::bus>(bus);
     sdbusp->request_name("xyz.openbmc_project.Ipmi.Host");

     cmdManager = std::make_unique<phosphor::host::command::Manager>(*sdbusp);

     // Activate OemRouter.
     oem::mutableRouter()->activate();

     // Register all the handlers that provider implementation to IPMI commands.
     ipmi_register_callback_handlers(HOST_IPMI_LIB_PATH);

     // Watch for BT messages
     r = sd_bus_add_match(bus, &ipmid_slot, FILTER, handle_ipmi_command, NULL);
     if (r < 0)
     {
         log<level::ERR>("Failed: sd_bus_add_match", entry("FILTER=%s", FILTER),
                         entry("ERRNO=0x%X", -r));
         goto finish;
     }

     // Attach the bus to sd_event to service user requests
     sd_bus_attach_event(bus, events, SD_EVENT_PRIORITY_NORMAL);

     {
         using namespace internal;
         using namespace internal::cache;
         sdbusplus::bus::bus dbus{bus};
         objects = std::make_unique<settings::Objects>(
             dbus, std::vector<settings::Interface>({restrictionModeIntf}));
         // Initialize restricted mode
         cache_restricted_mode();
         // Wait for changes on Restricted mode
         sdbusplus::bus::match_t restrictedModeMatch(
             dbus,
             sdbusRule::propertiesChanged(
                 objects->map.at(restrictionModeIntf).front(),
                 restrictionModeIntf),
             handle_restricted_mode_change);

         r = sd_event_loop(events);
     }

 finish:
     sd_event_unref(events);
     sd_bus_detach_event(bus);
     sd_bus_slot_unref(ipmid_slot);
     sd_bus_unref(bus);
     return r < 0 ? EXIT_FAILURE : EXIT_SUCCESS;
 }
	#include "config.h"

	#include "ipmid.hpp"

	#include "host-cmd-manager.hpp"
	#include "ipmiwhitelist.hpp"
	#include "sensorhandler.hpp"
	#include "settings.hpp"

	#include <assert.h>
	#include <dirent.h>
	#include <dlfcn.h>
	#include <errno.h>
	#include <sys/time.h>
	#include <systemd/sd-bus.h>
	#include <unistd.h>

	#include <algorithm>
	#include <cstring>
	#include <host-ipmid/ipmid-host-cmd.hpp>
	#include <host-ipmid/oemrouter.hpp>
	#include <iostream>
	#include <iterator>
	#include <map>
	#include <memory>
	#include <phosphor-logging/log.hpp>
	#include <sdbusplus/bus.hpp>
	#include <sdbusplus/bus/match.hpp>
	#include <sdbusplus/message/types.hpp>
	#include <sdbusplus/timer.hpp>
	#include <vector>
	#include <xyz/openbmc_project/Control/Security/RestrictionMode/server.hpp>

	using namespace phosphor::logging;
	namespace sdbusRule = sdbusplus::bus::match::rules;
	namespace variant_ns = sdbusplus::message::variant_ns;

	sd_bus* bus = NULL;
	sd_bus_slot* ipmid_slot = NULL;
	sd_event* events = nullptr;

	// Need this to use new sdbusplus compatible interfaces
	sdbusPtr sdbusp;

	// Global Host Bound Command manager
	using cmdManagerPtr = std::unique_ptr<phosphor::host::command::Manager>;
	cmdManagerPtr cmdManager;

	// Global timer for network changes
	std::unique_ptr<phosphor::Timer> networkTimer = nullptr;

	// Command and handler tuple. Used when clients ask the command to be put
	// into host message queue
	using CommandHandler = phosphor::host::command::CommandHandler;

	// Initialise restricted mode to true
	bool restricted_mode = true;

	FILE ipmiio, ipmidbus, *ipmicmddetails;

	void print_usage(void)
	{
	std::fprintf(stderr, "Options: [-d mask]\n");
	std::fprintf(stderr, " mask : 0x01 - Print ipmi packets\n");
	std::fprintf(stderr, " mask : 0x02 - Print DBUS operations\n");
	std::fprintf(stderr, " mask : 0x04 - Print ipmi command details\n");
	std::fprintf(stderr, " mask : 0xFF - Print all trace\n");
	}

	const char* DBUS_INTF = "org.openbmc.HostIpmi";

	const char* FILTER =
	"type='signal',interface='org.openbmc.HostIpmi',member='ReceivedMessage'";

	typedef std::pair<ipmi_netfn_t, ipmi_cmd_t> ipmi_fn_cmd_t;
	typedef std::pair<ipmid_callback_t, ipmi_context_t> ipmi_fn_context_t;

	// Global data structure that contains the IPMI command handler's registrations.
	std::map<ipmi_fn_cmd_t, ipmi_fn_context_t> g_ipmid_router_map;

	// IPMI Spec, shared Reservation ID.
	static unsigned short selReservationID = 0xFFFF;
	static bool selReservationValid = false;

	unsigned short reserveSel(void)
	{
	// IPMI spec, Reservation ID, the value simply increases against each
	// execution of the Reserve SEL command.
	if (++selReservationID == 0)
	{
	selReservationID = 1;
	}
	selReservationValid = true;
	return selReservationID;
	}

	bool checkSELReservation(unsigned short id)
	{
	return (selReservationValid && selReservationID == id);
	}

	void cancelSELReservation(void)
	{
	selReservationValid = false;
	}

	namespace internal
	{

	constexpr auto restrictionModeIntf =
	"xyz.openbmc_project.Control.Security.RestrictionMode";

	namespace cache
	{

	std::unique_ptr<settings::Objects> objects = nullptr;

	} // namespace cache
	} // namespace internal

	#ifndef HEXDUMP_COLS
	#define HEXDUMP_COLS 16
	#endif

	void hexdump(FILE* s, void* mem, size_t len)
	{
	unsigned int i, j;

	for (i = 0;
	i <
	len + ((len % HEXDUMP_COLS) ? (HEXDUMP_COLS - len % HEXDUMP_COLS) : 0);
	i++)
	{
	/* print offset */
	if (i % HEXDUMP_COLS == 0)
	{
	std::fprintf(s, "0x%06x: ", i);
	}

	/* print hex data */
	if (i < len)
	{
	std::fprintf(s, "%02x ", 0xFF & ((char*)mem)[i]);
	}
	else /* end of block, just aligning for ASCII dump */
	{
	std::fprintf(s, " ");
	}

	/* print ASCII dump */
	if (i % HEXDUMP_COLS == (HEXDUMP_COLS - 1))
	{
	for (j = i - (HEXDUMP_COLS - 1); j <= i; j++)
	{
	if (j >= len) /* end of block, not really printing */
	{
	std::fputc(' ', s);
	}
	else if (std::isprint(((char)mem)[j])) / printable char */
	{
	std::fputc(0xFF & ((char*)mem)[j], s);
	}
	else /* other char */
	{
	std::fputc('.', s);
	}
	}
	std::fputc('\n', s);
	}
	}
	}

	// Method that gets called by shared libraries to get their command handlers
	// registered
	void ipmi_register_callback(ipmi_netfn_t netfn, ipmi_cmd_t cmd,
	ipmi_context_t context, ipmid_callback_t handler,
	ipmi_cmd_privilege_t priv)
	{
	// Pack NetFn and Command in one.
	auto netfn_and_cmd = std::make_pair(netfn, cmd);

	// Pack Function handler and Data in another.
	auto handler_and_context = std::make_pair(handler, context);

	// Check if the registration has already been made..
	auto iter = g_ipmid_router_map.find(netfn_and_cmd);
	if (iter != g_ipmid_router_map.end())
	{
	log<level::ERR>("Duplicate registration", entry("NETFN=0x%X", netfn),
	entry("CMD=0x%X", cmd));
	}
	else
	{
	// This is a fresh registration.. Add it to the map.
	g_ipmid_router_map.emplace(netfn_and_cmd, handler_and_context);
	}

	return;
	}

	// Looks at the map and calls corresponding handler functions.
	ipmi_ret_t ipmi_netfn_router(ipmi_netfn_t netfn, ipmi_cmd_t cmd,
	ipmi_request_t request, ipmi_response_t response,
	ipmi_data_len_t data_len)
	{
	// return from the Command handlers.
	ipmi_ret_t rc = IPMI_CC_INVALID;

	// If restricted mode is true and command is not whitelisted, don't
	// execute the command
	if (restricted_mode)
	{
	if (!std::binary_search(whitelist.cbegin(), whitelist.cend(),
	std::make_pair(netfn, cmd)))
	{
	log<level::ERR>("Net function not whitelisted",
	entry("NETFN=0x%X", netfn), entry("CMD=0x%X", cmd));
	rc = IPMI_CC_INSUFFICIENT_PRIVILEGE;
	std::memcpy(response, &rc, IPMI_CC_LEN);
	*data_len = IPMI_CC_LEN;
	return rc;
	}
	}

	// Walk the map that has the registered handlers and invoke the approprite
	// handlers for matching commands.
	auto iter = g_ipmid_router_map.find(std::make_pair(netfn, cmd));
	if (iter == g_ipmid_router_map.end())
	{
	/* By default should only print on failure to find wildcard command. */
	#ifdef __IPMI_DEBUG__
	log<level::ERR>(
	"No registered handlers for NetFn, trying Wilcard implementation",
	entry("NET_FUN=0x%X", netfn) entry("CMD=0x%X", IPMI_CMD_WILDCARD));
	#endif

	// Now that we did not find any specific [NetFn,Cmd], tuple, check for
	// NetFn, WildCard command present.
	iter =
	g_ipmid_router_map.find(std::make_pair(netfn, IPMI_CMD_WILDCARD));
	if (iter == g_ipmid_router_map.end())
	{
	log<level::ERR>("No Registered handlers for NetFn",
	entry("NET_FUN=0x%X", netfn),
	entry("CMD=0x%X", IPMI_CMD_WILDCARD));

	// Respond with a 0xC1
	std::memcpy(response, &rc, IPMI_CC_LEN);
	*data_len = IPMI_CC_LEN;
	return rc;
	}
	}

	#ifdef __IPMI_DEBUG__
	// We have either a perfect match -OR- a wild card atleast,
	log<level::ERR>("Calling Net function",
	entry("NET_FUN=0x%X", netfn) entry("CMD=0x%X", cmd));
	#endif

	// Extract the map data onto appropriate containers
	auto handler_and_context = iter->second;

	// Creating a pointer type casted to char* to make sure we advance 1 byte
	// when we advance pointer to next's address. advancing void * would not
	// make sense.
	char* respo = &((char*)response)[IPMI_CC_LEN];

	try
	{
	// Response message from the plugin goes into a byte post the base
	// response
	rc = (handler_and_context.first)(netfn, cmd, request, respo, data_len,
	handler_and_context.second);
	}
	// IPMI command handlers can throw unhandled exceptions, catch those
	// and return sane error code.
	catch (const std::exception& e)
	{
	log<level::ERR>(e.what(), entry("NET_FUN=0x%X", netfn),
	entry("CMD=0x%X", cmd));
	rc = IPMI_CC_UNSPECIFIED_ERROR;
	*data_len = 0;
	// fall through
	}
	// Now copy the return code that we got from handler and pack it in first
	// byte.
	std::memcpy(response, &rc, IPMI_CC_LEN);

	// Data length is now actual data + completion code.
	data_len = data_len + IPMI_CC_LEN;

	return rc;
	}

	static int send_ipmi_message(sd_bus_message* req, unsigned char seq,
	unsigned char netfn, unsigned char lun,
	unsigned char cmd, unsigned char cc,
	unsigned char* buf, unsigned char len)
	{

	sd_bus_error error = SD_BUS_ERROR_NULL;
	sd_bus_message reply = NULL, m = NULL;
	const char dest, path;
	int r, pty;

	dest = sd_bus_message_get_sender(req);
	path = sd_bus_message_get_path(req);

	r = sd_bus_message_new_method_call(bus, &m, dest, path, DBUS_INTF,
	"sendMessage");
	if (r < 0)
	{
	log<level::ERR>("Failed to add the method object",
	entry("ERRNO=0x%X", -r));
	return -1;
	}

	// Responses in IPMI require a bit set. So there ya go...
	netfn \|= 0x01;

	// Add the bytes needed for the methods to be called
	r = sd_bus_message_append(m, "yyyyy", seq, netfn, lun, cmd, cc);
	if (r < 0)
	{
	log<level::ERR>("Failed add the netfn and others",
	entry("ERRNO=0x%X", -r));
	goto final;
	}

	r = sd_bus_message_append_array(m, 'y', buf, len);
	if (r < 0)
	{
	log<level::ERR>("Failed to add the string of response bytes",
	entry("ERRNO=0x%X", -r));
	goto final;
	}

	// Call the IPMI responder on the bus so the message can be sent to the CEC
	r = sd_bus_call(bus, m, 0, &error, &reply);
	if (r < 0)
	{
	log<level::ERR>("Failed to call the method", entry("DEST=%s", dest),
	entry("PATH=%s", path), entry("ERRNO=0x%X", -r));
	goto final;
	}

	r = sd_bus_message_read(reply, "x", &pty);
	if (r < 0)
	{
	log<level::ERR>("Failed to get a reply from the method",
	entry("ERRNO=0x%X", -r));
	}

	final:
	sd_bus_error_free(&error);
	m = sd_bus_message_unref(m);
	reply = sd_bus_message_unref(reply);

	return r < 0 ? EXIT_FAILURE : EXIT_SUCCESS;
	}

	void cache_restricted_mode()
	{
	restricted_mode = false;
	using namespace sdbusplus::xyz::openbmc_project::Control::Security::server;
	using namespace internal;
	using namespace internal::cache;
	sdbusplus::bus::bus dbus(ipmid_get_sd_bus_connection());
	const auto& restrictionModeSetting =
	objects->map.at(restrictionModeIntf).front();
	auto method = dbus.new_method_call(
	objects->service(restrictionModeSetting, restrictionModeIntf).c_str(),
	restrictionModeSetting.c_str(), "org.freedesktop.DBus.Properties",
	"Get");
	method.append(restrictionModeIntf, "RestrictionMode");
	auto resp = dbus.call(method);
	if (resp.is_method_error())
	{
	log<level::ERR>("Error in RestrictionMode Get");
	// Fail-safe to true.
	restricted_mode = true;
	return;
	}
	sdbusplus::message::variant<std::string> result;
	resp.read(result);
	auto restrictionMode = RestrictionMode::convertModesFromString(
	variant_ns::get<std::string>(result));
	if (RestrictionMode::Modes::Whitelist == restrictionMode)
	{
	restricted_mode = true;
	}
	}

	static int handle_restricted_mode_change(sd_bus_message* m, void* user_data,
	sd_bus_error* ret_error)
	{
	cache_restricted_mode();
	return 0;
	}

	static int handle_ipmi_command(sd_bus_message* m, void* user_data,
	sd_bus_error* ret_error)
	{
	int r = 0;
	unsigned char sequence, netfn, lun, cmd;
	const void* request;
	size_t sz;
	size_t resplen = MAX_IPMI_BUFFER;
	unsigned char response[MAX_IPMI_BUFFER];

	std::memset(response, 0, MAX_IPMI_BUFFER);

	r = sd_bus_message_read(m, "yyyy", &sequence, &netfn, &lun, &cmd);
	if (r < 0)
	{
	log<level::ERR>("Failed to parse signal message",
	entry("ERRNO=0x%X", -r));
	return -1;
	}

	r = sd_bus_message_read_array(m, 'y', &request, &sz);
	if (r < 0)
	{
	log<level::ERR>("Failed to parse signal message",
	entry("ERRNO=0x%X", -r));
	return -1;
	}

	std::fprintf(ipmiio,
	"IPMI Incoming: Seq 0x%02x, NetFn 0x%02x, CMD: 0x%02x \n",
	sequence, netfn, cmd);
	hexdump(ipmiio, (void*)request, sz);

	// Allow the length field to be used for both input and output of the
	// ipmi call
	resplen = sz;

	// Now that we have parsed the entire byte array from the caller
	// we can call the ipmi router to do the work...
	r = ipmi_netfn_router(netfn, cmd, (void)request, (void)response,
	&resplen);
	if (r != 0)
	{
	#ifdef __IPMI_DEBUG__
	log<level::ERR>("ERROR in handling NetFn", entry("ERRNO=0x%X", -r),
	entry("NET_FUN=0x%X", netfn), entry("CMD=0x%X", cmd));
	#endif
	resplen = 0;
	}
	else
	{
	resplen = resplen - 1; // first byte is for return code.
	}

	std::fprintf(ipmiio, "IPMI Response:\n");
	hexdump(ipmiio, (void*)response, resplen);

	// Send the response buffer from the ipmi command
	r = send_ipmi_message(m, sequence, netfn, lun, cmd, response[0],
	((unsigned char*)response) + 1, resplen);
	if (r < 0)
	{
	log<level::ERR>("Failed to send the response message");
	return -1;
	}

	return 0;
	}

	//----------------------------------------------------------------------
	// handler_select
	// Select all the files ending with with .so. in the given diretcory
	// @d: dirent structure containing the file name
	//----------------------------------------------------------------------
	int handler_select(const struct dirent* entry)
	{
	// To hold ".so" from entry->d_name;
	char dname_copy[4] = {0};

	// We want to avoid checking for everything and isolate to the ones having
	// .so.* or .so in them.
	// Check for versioned libraries .so.*
	if (strstr(entry->d_name, IPMI_PLUGIN_SONAME_EXTN))
	{
	return 1;
	}
	// Check for non versioned libraries .so
	else if (strstr(entry->d_name, IPMI_PLUGIN_EXTN))
	{
	// It is possible that .so could be anywhere in the string but unlikely
	// But being careful here. Get the base address of the string, move
	// until end and come back 3 steps and that gets what we need.
	strcpy(dname_copy, (entry->d_name + strlen(entry->d_name) -
	strlen(IPMI_PLUGIN_EXTN)));
	if (strcmp(dname_copy, IPMI_PLUGIN_EXTN) == 0)
	{
	return 1;
	}
	}
	return 0;
	}

	// This will do a dlopen of every .so in ipmi_lib_path and will dlopen
	// everything so that they will register a callback handler
	void ipmi_register_callback_handlers(const char* ipmi_lib_path)
	{
	// For walking the ipmi_lib_path
	struct dirent** handler_list;

	// This is used to check and abort if someone tries to register a bad one.
	void* lib_handler = NULL;

	if (ipmi_lib_path == NULL)
	{
	log<level::ERR>("No handlers to be registered for ipmi.. Aborting");
	assert(0);
	}
	else
	{
	// 1: Open ipmi_lib_path. Its usually "/usr/lib/phosphor-host-ipmid"
	// 2: Scan the directory for the files that end with .so
	// 3: For each one of them, just do a 'dlopen' so that they register
	// the handlers for callback routines.

	std::string handler_fqdn = ipmi_lib_path;

	// Append a "/" since we need to add the name of the .so. If there is
	// already a .so, adding one more is not any harm.
	handler_fqdn += "/";

	int num_handlers =
	scandir(ipmi_lib_path, &handler_list, handler_select, alphasort);
	if (num_handlers < 0)
	return;

	while (num_handlers--)
	{
	handler_fqdn = ipmi_lib_path;
	handler_fqdn += handler_list[num_handlers]->d_name;
	#ifdef __IPMI_DEBUG__
	log<level::DEBUG>("Registering handler",
	entry("HANDLER=%s", handler_fqdn.c_str()));
	#endif

	lib_handler = dlopen(handler_fqdn.c_str(), RTLD_NOW);

	if (lib_handler == NULL)
	{
	log<level::ERR>("ERROR opening",
	entry("HANDLER=%s", handler_fqdn.c_str()),
	entry("ERROR=%s", dlerror()));
	}
	// Wipe the memory allocated for this particular entry.
	free(handler_list[num_handlers]);
	}

	// Done with all registration.
	free(handler_list);
	}

	// TODO : What to be done on the memory that is given by dlopen ?.
	return;
	}

	sd_bus* ipmid_get_sd_bus_connection(void)
	{
	return bus;
	}

	sd_event* ipmid_get_sd_event_connection(void)
	{
	return events;
	}

	sd_bus_slot* ipmid_get_sd_bus_slot(void)
	{
	return ipmid_slot;
	}

	EInterfaceIndex getInterfaceIndex(void)
	{
	return interfaceKCS;
	}

	// Calls host command manager to do the right thing for the command
	void ipmid_send_cmd_to_host(CommandHandler&& cmd)
	{
	return cmdManager->execute(std::move(cmd));
	}

	cmdManagerPtr& ipmid_get_host_cmd_manager()
	{
	return cmdManager;
	}

	sdbusPtr& ipmid_get_sdbus_plus_handler()
	{
	return sdbusp;
	}

	int main(int argc, char* argv[])
	{
	int r;
	unsigned long tvalue;
	int c;

	// This file and subsequient switch is for turning on levels
	// of trace
	ipmicmddetails = ipmiio = ipmidbus = fopen("/dev/null", "w");

	while ((c = getopt(argc, argv, "h:d:")) != -1)
	switch (c)
	{
	case 'd':
	tvalue = strtoul(optarg, NULL, 16);
	if (1 & tvalue)
	{
	ipmiio = stdout;
	}
	if (2 & tvalue)
	{
	ipmidbus = stdout;
	}
	if (4 & tvalue)
	{
	ipmicmddetails = stdout;
	}
	break;
	case 'h':
	case '?':
	print_usage();
	return 1;
	}

	/* Connect to system bus */
	r = sd_bus_default_system(&bus);
	if (r < 0)
	{
	log<level::ERR>("Failed to connect to system bus",
	entry("ERRNO=0x%X", -r));
	goto finish;
	}

	/* Get an sd event handler */
	r = sd_event_default(&events);
	if (r < 0)
	{
	log<level::ERR>("Failure to create sd_event handler",
	entry("ERRNO=0x%X", -r));
	goto finish;
	}

	// Now create the Host Bound Command manager. Need sdbusplus
	// to use the generated bindings
	sdbusp = std::make_unique<sdbusplus::bus::bus>(bus);
	sdbusp->request_name("xyz.openbmc_project.Ipmi.Host");

	cmdManager = std::make_unique<phosphor::host::command::Manager>(*sdbusp);

	// Activate OemRouter.
	oem::mutableRouter()->activate();

	// Register all the handlers that provider implementation to IPMI commands.
	ipmi_register_callback_handlers(HOST_IPMI_LIB_PATH);

	// Watch for BT messages
	r = sd_bus_add_match(bus, &ipmid_slot, FILTER, handle_ipmi_command, NULL);
	if (r < 0)
	{
	log<level::ERR>("Failed: sd_bus_add_match", entry("FILTER=%s", FILTER),
	entry("ERRNO=0x%X", -r));
	goto finish;
	}

	// Attach the bus to sd_event to service user requests
	sd_bus_attach_event(bus, events, SD_EVENT_PRIORITY_NORMAL);

	{
	using namespace internal;
	using namespace internal::cache;
	sdbusplus::bus::bus dbus{bus};
	objects = std::make_unique<settings::Objects>(
	dbus, std::vector<settings::Interface>({restrictionModeIntf}));
	// Initialize restricted mode
	cache_restricted_mode();
	// Wait for changes on Restricted mode
	sdbusplus::bus::match_t restrictedModeMatch(
	dbus,
	sdbusRule::propertiesChanged(
	objects->map.at(restrictionModeIntf).front(),
	restrictionModeIntf),
	handle_restricted_mode_change);

	r = sd_event_loop(events);
	}

	finish:
	sd_event_unref(events);
	sd_bus_detach_event(bus);
	sd_bus_slot_unref(ipmid_slot);
	sd_bus_unref(bus);
	return r < 0 ? EXIT_FAILURE : EXIT_SUCCESS;
	}