ipmi_cmdlang man page on DragonFly

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ipmi_cmdlang(7)	       Shell interface to an IPMI system       ipmi_cmdlang(7)

NAME
       ipmi_cmdlang - A command language interface to the IPMI library

DESCRIPTION
       ipmi_cmdlang is a command language designed to supply the full power of
       OpenIPMI on a command line.  It has a  large  number  of	 commands  and
       well-formed  responses  to  each	 command.  Note that this assumes some
       knowledge of OpenIPMI and how it works; you can get that from the  IPMI
       document that comes with OpenIPMI.

       ipmish  starts  up with no connections or anything of that nature.  You
       must enter commands to make connections to domains.  Then you can enter
       commands to manipulate those domains or objects inside those domains.

       Note  that you may use quotes, either '' or  to contain parameters with
       spaces.

COMMENTS
       Lines with a # character in the first column are ignored.

OBJECTS
       In the command language, you will deal with various objects  like  sen‐
       sors,  controls, domains, and entities.	Each of these has a name.  The
       name of the domain is assigned by the user in the domain	 new  command,
       all  the	 other	names  are based on the domain name of the domain they
       belong to and various attributes about the object.  These names are all
       well-formed.  They are

       <domain>	 - A name of a domain.	Each registered domain in a system has
       a name assigned by the user.

       <entity> - Entity names are in the form:
	      [<domain>[(<entity spec>)]]
       Notice that the <entity spec> is optional.  If it is not	 listed,  then
       the  operation  is done on all entities in the domain.  The whole thing
       is optional, too, if nothing is given then the  operation  is  done  on
       every entity in every domain.

       The <entity spec> is either
	      <entity id>.<entity instance>
       for system-relative entities, or:
	      r<channel>.<IPMB>.<entity id>.<entity instance-0x60>
       for   device-relative   entities.    In	IPMI,  device-relative	entity
       instances always start at 0x60; the  specification  suggests  that  you
       subtract	 off  the 0x60 from the entity instance when displaying these;
       the command language follows this suggestion.

       <sensor> -  These come in the form
	      [<entity>[.name]]
       As with entities, only listing a domain will cause the operation to  be
       done  on	 every sensor in the domain, just listing an entity will cause
       it to be done to every sensor in that entity.  An  empty	 sensor	 entry
       will cause an operation to be done on every sensor in every domain.

       <control> - These come in the form
	      [<entity>[.name]]
       These work exactly like sensors.

       <mc> - A management controller.	These come in the form
	      [<domain>[(<channel>.<IPMB>)]]
       As  usual,  the parts left empty will cause defaulting to all things in
       the previously specified parts.

       <connection> - A connection number, in the form
	      [<domain>[.<integer>]]
       The number is the connection number of the domain.

       <pet> - A platform event trap id, in the form
	      [<domain>[.<integer>]]
       The number is arbitrarily assigned by the system.

       <lanparm> - A LAN parameter id, in the form
	      [<domain>[.<integer>]]
       The number is arbitrarily assigned by the system.

       <pef> - A PEF id, in the form
	      [<domain>[.<integer>]]
       The number is arbitrarily assigned by the system.

       <fru> - A FRU id, in the form
	      [<domain>[.<integer>]]
       The number is arbitrarily assigned by the system.

       In all cases, the object names have parts that are  optional,  and  the
       entire  object  name  is	 optional.   If a part is left empty, then all
       objects that are part of the specified  parts  are  operated  on.   For
       instance, if the system has a sensor named d1(7.1).temp then specifying
       d1 would operation on all sensors in the domain named  d1.   Specifying
       d1(7.1)	Would  operation on all sensors in that entity.	 Specifying an
       empty name, either with	or by just entering nothing if the  object  is
       the last thing in the command's parameters.

       Note  this optionality gives a lot of power, but can be very dangerous.
       Entering domain close will close every domain, for instance.

       In commands, every object operated on will generate a response for that
       object.	 If  no	 object	 is  operated  on, the command will produce an
       error.

OTHER PARAMETERS
       The commands and displays use a variety of other parameters for	speci‐
       fying various IPMI things.

       <guid>  - a 16-byte globally unique ID, all globbed together in one big
       hexadecimal thing.

       <threshold> is  a  threshold  for  a  sensor;  the  value  it  must  go
       over/under  to  generate	 an  event.   It is always displayed as one of
       lower non-critical lower critical lower non-recoverable upper non-crit‐
       ical upper critical upper non-recoverable.  It may be entered as one of
       the above, or as ln, lc, lr, un, uc, ur as a short form.

       <threshold enable> is the enable for a threshold.  It is like  <thresh‐
       old>  above, but also has a going-high or going-low and an assertion or
       deassertion appended to the end of the name.  The short form will  have
       a  l  or	 h for going-low and going high and then a a or d appended for
       assertion and deassertion  So for instance, urld is upper  non-recover‐
       able going-low deassertion.

       <discrete enable> is the enable or disable for a discrete sensor and is
       specified with the sensor offset.  The long form is <integer> assertion
       or  <integer> deassertion and the short form is <integer>[ad] where the
       number is the offset and [ad] means assertion or deassertion.

       <hot-swap state> is one of not_present,	inactive  activation_requested
       activation_in_progress	 active	   deactivation_requested    deactiva‐
       tion_in_progress or out_of_con.

       <color> is one of black, white, red, green blue yellow or orange.

       <bool> is one of true, on, t, or 1 for true and one of false,  off,  f,
       or 0 for false.	Output is always true or false.

COMMANDS
       The  command  language  is hierarchical, meaning that commands may have
       subcommands, and subcommands may have  subsubcommands,  etc.   So,  for
       instance, the command to create a domain is domain new.	The command to
       list all sensors in a domain named domain1 is sensor list domain1.

       Each command has a reponse for each object operated on, which is listed
       after  the  command  description.   In  those  responses, anything that
       begins with a % is optional.  Entries of the  form  **name**  refer  to
       object  info  descriptions  that are listed in the object info section.
       If an entry has two '.' indented one space below it,  then  that	 entry
       may occur zero or more times.

       Each section below defines the unique subcommands of a main command.

       Help for any command is available with:

       help command [subcommand [...]]	- Help for any command.

       Some commands are common to almost all subcommands.  These are:

       list  <containing object> - List all objects of the specified type that
       are contained in the specified  object.	 For  instance,	 control  list
       <entity> will list all controls in the given entity.

       Response:
	      <containing object type>
		Name: <name>
		 .
		 .

       info <object> - List static information about the given object.

       Response:
	      <object type>
		Name: <name>
		**object info**

   domain
       These commands deal with domain objects.

       new  <domain>  <options> <parms> [<parms>] - Open a connection to a new
       domain.	<parms> are either:
	      lan <IP> <port> [<IP> <port>] <enc> <auth> <name> <password>
       for a RMCP LAN connection or
	      smi <smi num>
       for a system interface connection.  Note that <parms> is	 listed	 twice
       (second	one  is	 optional);  if the system support it you can make two
       connections to two independent management controllers  in  the  system.
       Note  that  this is not for multiple IP addresses to the same BMC.  For
       that, notice that the LAN connection has an options extra IP  and  port
       for  the	 second	 IP address.  OpenIPMI supports these IP addresses and
       connection, detecting failures, switching between addresses, and	 other
       fault-tolerant  things.	It does this transparently to the user.	 Muti‐
       ple connections may require special OEM support, read the documentation
       about your specific system if you need this.

       The  <IP> is the IP address or host name of the LAN-capable BMC to con‐
       nect with.  The <port> is generally 623.	 <enc> is  the	authentication
       type, either md5, md2, straight, or none.  <auth> is the authentication
       level, either admin, operator or user.  <name> and <password>  are  the
       user name and password of the IPMI user to use for the connection.  The
       <smi num> is the driver number, generally 0.  Options enable  and  dis‐
       able various automitic processing and are:
       -[no]all	 -  all automatic handling.  This will override the other pro‐
	      cessing options and turn them all on.  This is true by default.
       -[no]sdrs - sdr fetching.  This turns on fetching SDRs  when  they  are
	      found.  This is false by default.
       -[no]frus  -  FRU fetching  This turns on fetching FRU information when
	      it is found.  This is false by default.
       -[no]sel - SEL fetching.	   This turns on fetching SELs when  they  are
	      found.  This is false by default.
       -[no]ipmbscan  - IPMB bus scanning.  This turns on scanning IPMB busses
	      when they are found.  This is false by default.
       -[no]oeminit - enable or disable special OEM processing (like ATCA).
       -[no]seteventrcvr - setting event receivers.  Note that	setting	 event
	      receivers and waiting til up is not affected by the -all option.
	      If this is true (the default) then OpenIPMI will attempt to  set
	      the  event receiver for an MC it finds that does not have it set
	      to a valid destination.
       -wait_til_up - wait until the domain is up before returning  Note  that
	      if  you  specify	this  and  the domain never comes up, you will
	      never get a prompt.  This is not affected by  the	 -all  option.
	      By  default  -all and -seteventrcvr are true, which turns every‐
	      thing on.

       Response:
	      Domain Created: <domain>

       open <domain> <options> <parms> [<parms>] - Open a connection to a  new
       domain.	<parms> are either:
	      lan [-U <username>] [-P <password>] [-A <authtype>]
		[-L <privilege>] [-s] [-p[2] <port number>]
		[-Ra <auth alg>] [-Ri <integ alg>] [-Rc <conf algo>]
		[-Rl] [-Rk <bmc key>] [-H <hackname>]
		[-M <max oustanding msgs>] <IP> [<IP>]
       for a RMCP/RMCP+ LAN connection or
	      smi <smi num>
       for  a  system interface connection.  Note that <parms> is listed twice
       (second one is optional); if the system support it  you	can  make  two
       connections  to	two  independent management controllers in the system.
       Note that this is not for multiple IP addresses to the same  BMC.   For
       that,  use  the -s option and the second IP (and -p2) for the second IP
       address.	 OpenIPMI supports these IP addresses and connections, detect‐
       ing  failures,  switching  between  addresses, and other fault-tolerant
       things.	It does this transparently to the user.	 Multiple  connections
       may require special OEM support, read the documentation about your spe‐
       cific system if you need this.

       The <IP> is the IP address or host name of the LAN-capable BMC to  con‐
       nect  with.  The <port> defaults 623.  <authtype> is the authentication
       type, either rmcp+, md5, md2, straight, or none.	 It  defaults  to  the
       best authentication supported by the server.  <auth> is the authentica‐
       tion level, either admin, operator or  user.   It  defaults  to	admin.
       <username>  and	<password>  are the user name and password of the IPMI
       user to use for the connection.	For RMCP+ connections, the authentica‐
       tion    algorithms    supported	  (-Ra)	  are:	 bmcpick,   rakp_none,
       rakp_hmac_sha1, and rakp_hmac_md5.  The integrity algorithms (-Ri) sup‐
       ported are: bmcpick, none, hmac_sha1, hmac_md5, and md5.	 The confiden‐
       tiality algorithms  (-Rc)  are:	bmcpick,  aes_cbc_128,	xrc4_128,  and
       xrc_40.	 The  defaults are rackp_hmac_sha1, hmac_sha1, and aes_cb_128.
       -Rl turns on lookup up names  by	 the  name  and	 the  privilege	 level
       (allowing  the  same name with different privileges and different pass‐
       words), the default is straight name lookup.  -Rk  sets	the  BMC  key,
       needed if the system does two-key lookups.

       For SMI types, the <smi num> is the driver number, generally 0.

       The <hackname> enables certain hacks for broken platforms.  This may be
       listed multiple times to enable multiple hacks.	The  currently	avail‐
       able hacks are:
       intelplus - For Intel platforms that have broken RMCP+.
       rakp3_wrong_rolem - For systems that truncate role(m) in the RAKP3 msg.
       rmcpp_integ_sik	-  For	systems	 that  use  SIK	 instead  of  K(1) for
	      integrity.

	      The -M  option  sets  the	 maximum  outstanding  messages.   The
	      default is 2, ranges 1-63.

	      Options enable and disable various automitic processing and are:
       -[no]all	 -  all automatic handling.  This will override the other pro‐
	      cessing options and turn them all on.  This is true by default.
       -[no]sdrs - sdr fetching.  This turns on fetching SDRs  when  they  are
	      found.  This is false by default.
       -[no]frus  -  FRU fetching  This turns on fetching FRU information when
	      it is found.  This is false by default.
       -[no]sel - SEL fetching.	   This turns on fetching SELs when  they  are
	      found.  This is false by default.
       -[no]ipmbscan  - IPMB bus scanning.  This turns on scanning IPMB busses
	      when they are found.  This is false by default.
       -[no]oeminit - enable or disable special OEM processing (like ATCA).
       -[no]seteventrcvr - setting event receivers.  Note that	setting	 event
	      receivers	 is  not affected by the -all option.  If this is true
	      (the default) then  OpenIPMI  will  attempt  to  set  the	 event
	      receiver for an MC it finds that does not have it set to a valid
	      destination.  -[no]setseltime - set SEL time.  Note that setting
	      the  SEL	time  is  not affected by the -all option.  If this is
	      true (the default) then OpenIPMI will attempt to set the time in
	      the SELs it finds.  It will set it to the current system time.
       -wait_til_up  -	wait until the domain is up before returning Note that
	      if you specify this and the domain  never	 comes	up,  you  will
	      never  get  a  prompt.  This is not affected by the -all option.
	      By default -all and -seteventrcvr are true, which	 turns	every‐
	      thing on.

       Response:
	      Domain Created: <domain>

       fru  <domain>  <is_logical>  <device_address>  <device_id>  <lun> <pri‐
       vate_bus> <channel> - dump a fru given all it's insundry information.

       Response:
	      Domain
		Name: <domain>
		FRU
		  **FRU INFO**

       msg <domain> <channel> <ipmb> <LUN> <NetFN> <Cmd> [data...]  -  Send  a
       command	to the given IPMB address on the given channel and display the
       response.  Note that this does not require the existance of  an	MC  in
       OpenIPMI.

       Response:
		Domain: <domain>
		channel: <chan>
		ipmb: <ipmb>
		LUN: <lun>
		NetFN: <netfn>
		command: <cmd>
		Data: <data bytes>

       scan  <domain>  <ipmb addr> [ipmb addr] - scan an IPMB to add or remove
       it.  If a range is given, then scan all IPMBs in the range.

       Response:
	      Scan done: <domain>

       rescan_sels <domain> - Rescan all the SELs in the domain.

       Response:
	      SEL Rescan done: <domain>

       presence <domain> - Audit the presence of all enities  in  the  domain.
       Note that this just starts the process; it will run in the background.

       Response is:
	      Presence check started: <domain>

       close <domain> - close the given domain.

       Response:
	      Domain closed: <domain>

       sel_rescan_time	<domain>  <time in seconds> - Set the time between SEL
       rescans for all.	 It affects all current SELs and SELs that are discov‐
       ered in the future.  Zero disables scans.

       Response:
	      Domain SEL rescan time set: <domain>

       ipmb_rescan_time <domain> <time in seconds> - Set the time between IPMB
       rescans for this domain.	 zero disables scans.

       Response:
	      Domain IPMB rescan time set: <domain>

   fru
       These commands deal with FRU objects.  Note that FRU objects are	 allo‐
       cated by the domain fru command, and are not allocated here.

       list - List all the frus in the system

       Response:
	      Domain
		Name: <domain>
		FRUs
		  Name: <fru>
		 .
		 .
	       .
	       .

       info <fru> - Dump information about a FRU

       Response:
	      **FRU INFO**

       areainfo <fru> - Dump the info about the FRU's areas

       Response:
	      FRU
		Name: <fru>
		FRU Length: <integer>
		Area
		  Name: <area name>
		  Number: <integer>
		  Offset: <integer>
		  Length: <integer>
		  Used Length: <Integer>
		 .
		 .

       write <fru> - Write the local FRU data out into the FRU

       Response:
	      FRU written: <fru>

       close <fru> - Delete the FRU

       Response:
	      FRU deleted: <fru>

       setval  <fru> <name> [num] value - Set the value of a FRU element.  The
       name is the record name, or multi-record.  The number is	 required  for
       fields  that need it (custom and multi-record).	The value is an a sin‐
       gle value for integers.	For  strings  it  is  a	 string	 type  (either
       binary,	ascii,	or  unicode) and the info.  Binary and unicode data is
       specified as numbers.  ascii data is specified in a string.  Note  that
       setting a ascii value with no string will clear the value.  Zero length
       strings and data is valid.

       Response:
	      FRU value set: <fru>

       area_offset <fru> <area name> <offset> - Set the offset	of  the	 given
       area  to	 the given value.  Area names are internal_data, chassis_info,
       board_info, product_info, and multi_record.

       Response:
	      FRU area offset set: <fru>

       area_length <fru> <area name> <length> - Set the length	of  the	 given
       area  to	 the  given value.  Area names are internal_data, chassis_info
       board_info, product_info, and multi_record

       Response:
	      FRU area length set: <fru>

       area_add <fru> <area name> <offset> <length> - Add the  given  area  to
       the FRU.

       Response:
	      FRU area added: <fru>

       area_delete <fru> <area name> - Delete the given area from the FRU

       Response:
	      FRU area deleted: <fru>

   entity
       These commands deal with entity objects.

       list <entity> - List all the entities that meed the criteria

       Response:
	      Domain
		Name: <domain>
		Entities
		  Name: <entity>
		   .
		   .
	       .
	       .

       info <entity> - Dump information about an entity.

       Reponse:
	      Entity
		Name: <entity>
		**ENTITY INFO**
	       .
	       .

       fru <entity> - Dump the FRU information about the given entity.

       Reponse:
	      Entity
		Name: <entity>
		FRU
		  **FRU INFO**

   entity hs
       These  commands	deal with hot-swap of entities.	 Note that there is no
       info or list command for this subcommand.

       get_act_time <entity> - Get the hot-swap auto-activate time.

       Response:
	      Entity
		Name: <entity>
		  Auto-Activation Time: <integer>

       set_act_time <entity> - Set the hot-swap auto-activate time.

       Reponse:
	      Set act time: <entity>

       get_deact_time  <entity>	 -  Get	 the  hot-swap	auto-deactivate	  time
       Response:
	      Entity
		Name: <entity>
		   Auto-Deactivation Time: <integer>

       set_deact_time <entity> - Set the hot-swap auto-deactivate time

       Response:
	      Set deact time: <entity>

       activation_request  <entity>  - Act like a user requested an activation
       of the entity.  This is generally  equivalent  to  closing  the	handle
       latch or something like that.

       Response:
	      Activation requested: <entity>

       activate <entity> - activate the given entity

       Response:
	      Activated: <entity>

       deactivate <entity> - deactivate the given entity

       Response:
	      Deactivated: <entity>

       state <entity> - Return the current hot-swap state of the given entity.

       Response:
	      Entity
		Name: <entity>
		  State: <hot-swap state>

       check <entity> - Audit the entity's hot-swap state

       Response:
	      Check started: <entity>

   sensor
       get <sensor> - Get the sensor's current reading.

       Response:
	      Sensor
		Name: <sensor>
		Event Messages Enabled: <bool>
		Sensor Scanning Enabled: <bool>
		Initial Update In Progress: <bool>
       For threshold sensors, the following will be output:
	      %Value: <double>
	      %Raw Value: <integer>
	      Threshold
		Name: <threshold>
		Out Of Range: <bool>
       For discrete sensors, the following will be output:
	      Event
		Offset: <integer>
		%Name: <string name of event offset>
		Set: <bool>
       The name field may be custom and is not explicitly specified.

       rearm  <sensor>	global	| <threshold enable> [<threshold enable> ..] |
       <discrete enable> [<discrete enable>  ..]   -  Rearm  the  sensor.   If
       global  is  specified, then rearm all events in the sensor.  Otherwise,
       if it is a threshold sensor, then put in a list of  threshold  enables.
       If it is a discrete sensor, then put in a list of discrete enables.

       Response:
	      Rearm done: <sensor>

       get_thresholds <sensor> - Get the sensor's thresholds

       Response:
	      Sensor
		Name: <sensor>
		Threshold
		  Name: <threshold>
		  Value: <double>

       set_thresholds  <sensor>	 <threshold>  <value>  ...  - Set the sensor's
       thresholds to the given values.	If a threshold is  not	specified,  it
       will  not  be  modified.	 Thresholds are un, uc, ur, lr, lc, ln.	 The u
       stands for upper, l for lower, n for non-critical, c for critical,  and
       r for non-recoverable.  The value is floating point.

       Response:
	      Thresholds set: <sensor>

       get_hysteresis <sensor> - Get the sensor's hysteresis values

       Response:
	      Sensor
		Name: <sensor>
		Positivie Hysteresis: <integer>
		Negative Hysteresis: <integer>

       set_hysteresis  <sensor>	 <pos hyst> <neg hyst> - Set the sensor's hys‐
       teresis to the given values.  These are raw integer value; hystersis is
       specified  as  a raw value and it cannot be converted to floating point
       because the function may be non-linear.

       Response:
	      Hysteresis set: <sensor>

       get_event_enables <sensor> - Get the sensor's event enable values

       Response:
	      Sensor
		Name: <sensor>
		Event Messages Enabled: <bool>
		Sensor Scanning Enabled: <bool>
		Busy: <bool>
       Threshold sensors report:
	      Threshold
		Name: <threshold>
		Enabled: <bool>
		 .
		 .
       only supported thresholds are listed.  Discrete sensors report:
	      Event
		Offset: <integer>
		Name: <event offset name for sensor>
		%Assertion Enabled: <bool>
		%Deassertion Enabled: <bool>
       only supported offsets  are  listed.   The  assertion  and  deassertion
       enables are listed only if the offset support them.

       set_event_enables  <sensor>  msg|nomsg  scan|noscan [<enable> [<enable>
       ...]]  - Set the sensor's event enable values.  This turns sensor  mes‐
       sages  and  scanning  on and off and will enable all the listed enables
       and disable all over ones.  The enables are either a <threshold enable>
       or a <discrete enable>.

       Response:
	      Event enables set: <sensor>

       enable_events  <sensor> msg|nomsg scan|noscan [<enable> [<enable> ...]]
       - Enable event enable values.  This turns sensor messages and  scanning
       on  and	off and will enable all the listed enables.  All other enables
       will be left alone.  The enables are either a <threshold enable>	 or  a
       <discrete enable>.

       Response:
	      Event enables set: <sensor>

       disable_events <sensor> msg|nomsg scan|noscan [<enable> [<enable> ...]]
       - Disable event enable values.  This turns sensor messages and scanning
       on  and	off and will disable all the listed enable.  All other enables
       will be left alone.  The enables are either a <threshold enable>	 or  a
       <discrete enable>.

       Response:
	      Event enables set: <sensor>

   control
       Commands dealing with controls.

       set  <control> <value> [<value> ..]  - Set the value of a control.  The
       settings depend on control type, most take one or more  integer	values
       depending  on  the  number of physical things the control contains.  An
       identifier type takes one or more unsigned  characters.	 A  light  set
       with settings take the form
	      lc|nolc <color> <on time> <off time>
       lc  and	nolc  turn  on	or of local control, the over values should be
       obvious.	 Note all lights support local control, you need to see if  it
       supports the value.

       Response:
	      Set done: <control>

       get <control> - Get the value of a control.  The reponse depends on the
       control type.

       Response:
	      Control
		Name: <control>
       Response for setting lights is:
	      Light
		Num: 0
		Local Control: <bool>
		%Color: <color>
		%On Time: <integer>
		%Off Time: <integer>
       Note that multiple lights may be present if the control supports multi‐
       ple lights.  The options values (marked with % ) will not be present if
       local control is set to true.  Local control means that the  LED	 takes
       whatever	 default  function  it does on the device (like disk activity,
       ethernet activity, hot-swap LED, etc.).	Response for id control:
	      Data: <byte1> <byte2> ...
       Response for other controls:
	      Value
		Num: <integer>
		Value: <integer>
       There will be one Value for each value the control supports.

   mc
       Commands dealing with MC objects.

       reset <warm | cold> <mc> - Do a warm or cold reset on the given MC

       Response:
	      Reset done: <mc>

       msg <mc> <LUN> <NetFN> <Cmd> [data...]  - Send the given command to the
       management controller and display the response.

       Response:
		MC: <mc>
		LUN: <lun>
		NetFN: <netfn>
		command: <cmd>
		Data: <data bytes>

       set_events_enable  <mc> <enable | disable> - enables or disables events
       on the MC.

       Response:
	      Events enable done: <mc>

       get_events_enable <mc> - Prints out if the events are enabled  for  the
       given MC.

       Response:
	      Events Enable: <bool>

       sdrs  <mc> <main | sensor> - list the SDRs for the mc.  Either gets the
       main SDR repository or the sensor SDR repository.

       Response:
	      MC
		Name: <mc>
		SDR
		  Record ID: <integer>
		  Type: <integer>
		  Version: <integer>.<integer>
		  Data: <data bytes>
       One SDR will be present for each SDR in the repository.

       get_sel_time <mc> - Get the time in the SEL for the given MC.

       Response:
	      MC
		Name: <mc>
		SEL Time: <integer>

       set_sel_time <mc> <time> - Set the time in the SEL for the given MC.

       Response:
	      MC SEL time set
		Name: <mc>

       rescan_sel <mc> - Rescan the SEL in the MC.

       Response:
	      SEL Rescan done: <mc>

       sel_rescan_time <mc> <time in seconds> - Set the time between SEL  res‐
       cans for the SEL on this MC.  Zero disables scans.

       Response:
	      MC SEL rescan time set: <domain>

       sel_info <mc> - Dump information about the MC's SEL.

       Response:
	      MC
		Name: <mc>
		SEL Version: <integer>.<integer>
		SEL Count: <integer>
		SEL Slots Used: <integer>
		SEL Free Bytes: <integer>
		SEL Last Addition Timestamp: <integer>
		SEL overflow: <bool>
		SEL Supports Delete: <bool>
		SEL Supports Partial Add: <bool>
		SEL Supports Reserve: <bool>
		SEL Supports Get SEL Allocation: <bool>

       chan info <mc> <channel> - Dump information about the MC's channel.

       Response:
	      Channel Info
		MC: <mc>
		Number: <integer>
		Medium: <integer>
		Protocol Type: <integer>
		Session Support: session-less|single-session|multi-session|session-based
		Vendor ID: <data bytes>
		Aux Info: <data bytes>

       chan  get_access <mc> <channel> non-volatile|present|both - Dump infor‐
       mation about the MC's channel access.  There are two  different	places
       where this is stored, the present in-use values (volatile) and the non-
       volatile storage that is loaded at startup.  Note if you specify	 chan‐
       nel 0xe, the response channel will be different; it will be the current
       channel.

       Response:
	      Channel Access
		MC: <mc>
		Channel: <integer>
		Type: non-volatile|present
		Alerting Enabled: <bool>
		Per-Message Auth: <bool>
		User Auth: <bool>
		Access Mode: disable|pre-boot|always|shared
		Privilege Limit: callback|user|operator|admin|oem

       chan set_access <mc> <channel> non-volatile|present|both <parm> <value>
       ...   -	Set  information about the MC's channel access.	 There are two
       different places where  this  is	 stored,  the  present	in-use	values
       (volatile)  and	the  non-volatile  storage  that is loaded at startup.
       Note if you specify channel 0xe, the modified channel will be the  cur‐
       rent channel.  Parms are:
	      alert true|false
	      msg_auth true|false
	      user_auth true|false
	      access_mode disabled|pre-boot|always|shared
	      privilege_limit callback|user|operator|admin|oem

       Response:
	      Channel Access Set
		MC: <mc>
		Channel: <integer>

       chan user list <mc> <channel> [<user num>] - List users associated with
       the channel.  Each user number has an associated name and password that
       is  global  in  the  MC (not associated with a channel).	 There is also
       channel-specific information for each user.   This  command  lists  the
       global  user  information  and the channel-specific information for the
       channel specified.  If no user number is listed, then all users for the
       channel are listed.  Otherwise only the given user is listed.

       Response:
	      Channel Access Set
		MC: <mc>
		Channel: <integer>
		Max User: <integer>
		Enabled Users: <integer>
		Fixed Users: <integer>
		User
		  Number: <integer>
		  *String Name: <string>
		  *Binary Name: <data bytes>
		 Link Auth Enabled: <bool>
		 Msg Auth Enabled: <bool>
		 Access CB Only: <bool>
		 Privilege Limit: <integer>
		 Session Limit: <integer>
		.
		.
       All  the	 users	are  listed.   One  of	string	name or binary name is
       present, if the name is not a printable string, then the binary data is
       dumped.

       chan  user  set	<mc>  <channel>	 <user	num> <parm> <value> ...	 - Set
       information about the user number.  Only the specified values are modi‐
       fied.   The name and password are global values, all other are channel-
       specific.  The parms are: are:
	      link_enabled true|false
	      msg_enabled true|false
	      cb_only true|false
	      privilege_limit callback|user|operator|admin|oem|no_access
	      session_limit <integer>
	      name <user name string>
	      password <password string, <= 16 characters>
	      password2 <password string, <= 20 characters>
	      enable
	      disable
       The password is the 16-byte IPMI 1.5 passwords., the password2  is  for
       20-byte	IPMI  2.0  passwords.	Note that setting the session limit to
       zero means there is no session limit.  Also note that some systems have
       a bug where the session limit is not optional (as the spec says it is).
       If you get C7 errors back from this command, you will  have  to	always
       specify	the  session limit.  Note that you must enable the user for it
       to work, but there seems to be no way to get if the user is enabled  or
       not.

       Response:
	      User Info Set: <mc>

   sel
       Commands dealing with the system event log.  Note that there is no info
       command.

       list <domain> - The list command is unique in this  object,  so	it  is
       specified explicitly here.  List the local copy of the system event log
       for the entire domain.

       Response:
	      Domain
		Name: <domain>
		Entries: <integer>
		Slots in use: <integer>
		Event
		  **EVENT INFO**
		 .
		 .

       mc_list <domain> - List the local copy of the system event log  on  the
       given MC.

       Response:
	      MC
		Name: <mc>
		Entries: <integer>
		Slots in use: <integer>
		Event
		  **EVENT INFO**
		 .
		 .

       delete <mc> <record #> - Delete the given event number from the SEL

       Response:
	      Event deleted
		MC: <mc>
		Record: <integer>

       add <mc> <type> <13 bytes of data> - Add the event data to the SEL.

       Response:
	      MC
		Name: <mc>
		Record ID: <integer>

       clear <domain> - clear the system event log

       Response:
	      SEL Clear done: <domain>

   con
       Commands dealing with connections.

       activate <connection> - Activate the given connection

       Response:
	      Connection activated: <connection>

   pet
       Commands dealing with platform event traps.

       new <domain> <connection> <channel> <ip addr> <mac_addr> <eft selector>
       <policy num> <apt selector> <lan dest selector> - Set up the domain  to
       send  PET  traps	 from the given connection to the given IP/MAC address
       over the given channel.

       Response:
	      PET Created: <pet>

       mcnew <mc> <channel> <ip addr> <mac_addr> <eft selector>	 <policy  num>
       <apt  selector>	<lan  dest  selector>  - Set up the domain to send PET
       traps from the given connection to the given IP/MAC  address  over  the
       given channel.  This takes an MC instead of a connection.

       Response:
	      PET Created: <pet>

       close <pet> - Close the pet.

       Response:
	      PET destroyed: <pet>

   pef
       commands	 dealing with platform even filters.  These are basically con‐
       nections to the PEF configuration parameters in an MC.  You use	a  pef
       to  fetch a pef config, which you can then modify and write back to the
       MC.  Note that when you get a pef config, you claim a lock  on  the  MC
       that must be unlocked.

       new <mc> - Create a pef for the given MC.

       Response:
	      PEF: <pef>

       unlock_mc <mc> - Unlock the PEF lock on the given MC.

       Response:
	      PEF unlocked: <mc>

       close <pef> - Free the given pef

       Response:
	      PEF destroyed: <pef>

   pef config
       Commands	 dealing  with	PEF  configurations.  These are the actual PEF
       data items.

       get <pef> - Fetch the pef data items from the pef and create a pef con‐
       fig.

       Response:
	      PEF Config
		Name: <pef config>
		**PEF CONFIG**

       update <pef config> <parm> [selector] <value> - Set the given parameter
       in the pef config to the given value.  If the parameter has a  selector
       of  some type, the selector must be given, otherwise no selector should
       be given.

       Response:
	      PEF config updated: <pef config>

       set <pef> <pef config> - Write the pef data back to the pef.  Note that
       this must be the same pef used to create the config.

       Response:
	      PEF config set: <pef config>

       unlock  <pef> <pef config> - Unlock the lock in the MC and mark the pef
       config as unlocked.

       Response:
	      PEF config unlocked: <pef config>

       close <pef config> - Free the pef config.

       Response:
	      PEF config destroyed: <pef config>

   lanparm
       Commands dealing with lanparms.	These are basically connections to the
       LAN  configuration  parameters  in an MC.  You use a lanparm to fetch a
       lanparm config, which you can then modify and write  back  to  the  MC.
       Note  that  when	 you  get a lanparm config, you claim a lock on the MC
       that must be unlocked.

       new <mc> <channel> - Create a lanparm for the given MC and channel.

       Response:
	      LANPARM: <lanparm>

       unlock_mc <mc> <channel> - Unlock the lanparm lock on the given MC  and
       channel.

       Response:
	      LANPARM unlocked: <mc>

       close <lanparm> - Free the given lanparm

       Response:
	      LANPARM destroyed: <lanparm>

   lanparm config
       Commands	 dealing  with	lanparm	 configurations.  These are the actual
       lanparm data items.

       get <lanparm> - Fetch the lanparm data items from the lanparm and  cre‐
       ate a lanparm config.

       Response:
	      LANPARM Config
		Name: <lanparm config>
		**LANPARM CONFIG**

       set  <lanparm>  <lanparm	 config>  - Write the lanparm data back to the
       lanparm.	 Note that this must be the same lanparm used  to  create  the
       config.

       Response:
	      LANPARM config set: <lanparm config>

       unlock  <lanparm> <lanparm config> - Unlock the lock in the MC and mark
       the lanparm config as unlocked.

       Response:
	      LANPARM config unlocked: <lanparm config>

       close <lanparm config> - Free the lanparm config.

       Response:
	      LANPARM config destroyed: <lanparm config>

OTHER COMMANDS
       A few general commands exist.

       evinfo <bool> - Turn on or off dumping object information when an event
       comes in.  This is false by default.

       debug <type> <bool> - Turn the given debugging type on or off

EVENTS
       The  command  language will output events to the console when they hap‐
       pen.  Events all occur in the format:
		Event
		  **EVENT INFO**

       The event info varies on the type of events.  The  defined  events  are
       listed  below.  Note that the output of some events depends on the set‐
       ting of the evinfo command; the information about the object itself may
       or may not be output.

       Some  events  have another event container; this is the IPMI event that
       caused the event to be output.

       The following event is output when the  domain  is  completely  up  and
       operational and finished all it SDR, FRU, and bus scans:
		EVENT
		  Object Type: Domain
		  Name: <domain>
		  Operation: Domain fully up
		  Connection Number: <integer>
		  Port Number: <integer>
		  Any Connection Up: <bool>
		  Error: <integer>

       The following comes out when domain connection infomration changes:
		EVENT
		  Object Type: Domain
		  Name: <domain>
		  Operation: Connection Change

       The following comes out when domains are added:
		EVENT
		  Object Type: Domain
		  Name: <domain>
		  Operation: Add
		  %**DOMAIN INFO**

       The following comes out when domains are destroyed:
		EVENT
		  Object Type: Domain
		  Name: <domain>
		  Operation: Delete

       The  following  comes  out  when the domain gets an event that does not
       have a handler:
		EVENT
		  Object Type: Event
		  **EVENT INFO**

       The following comes out when an entity is added:
		EVENT
		  Object Type: Entity
		  Name: <entity>
		  Operation: Add
		  %**ENTITY INFO**

       The following comes out when an entity is deleted:
		EVENT
		  Object Type: Entity
		  Name: <entity>
		  Operation: Delete

       The following comes out when an entity is changed:
		EVENT
		  Object Type: Entity
		  Name: <entity>
		  Operation: Change
		  %**ENTITY INFO**

       The following comes out when an entity's FRU is added:
		EVENT
		  Object Type: Entity FRU
		  Name: <entity>
		  Operation: Add
		  %**FRU INFO**

       The following comes out when an entity's FRU is deleted:
		EVENT
		  Object Type: Entity FRU
		  Name: <entity>
		  Operation: Delete

       The following comes out when an entity's FRU is changed:
		EVENT
		  Object Type: Entity FRU
		  Name: <entity>
		  Operation: Change
		  %**FRU INFO**

       The following comes out when an entity's presence changes:
		EVENT
		  Object Type: Entity
		  Name: <entity>
		  Operation: Presence Change
		  Present: <bool>
		  %Event
		    **EVENT INFO**

       The following comes out when an entity's hot-swap state changes:
		EVENT
		  Object Type: Entity
		  Name: <entity>
		  Operation: Hot-Swap Change
		  Last State: <hot-swap state>
		  State: <hot-swap state>
		  %Event
		    **EVENT INFO**

       The following comes out when an MC is added:
		EVENT
		  Object Type: MC
		  Name: <mc>
		  Operation: Add
		  %**MC INFO**

       The following comes out when an MC is removed:
		EVENT
		  Object Type: MC
		  Name: <mc>
		  Operation: Delete

       The following comes out when an MC is changed:
		EVENT
		  Object Type: MC
		  Name: <mc>
		  Operation: Change
		  %**MC INFO**

       The following comes out when an MC changes active state:
		EVENT
		  Object Type: MC
		  Name: <mc>
		  Operation: Active Changed
		  Active: <bool>

       The following comes out when a discrete sensor gets an event:
		EVENT
		  Object Type: Sensor
		  Name: <sensor>
		  Operation: Event
		  Offset: <integer>
		  Direction: assertion | deassertion
		  Severity: <integer>
		  Previous Severity: <integer>
		  %Event
		    **EVENT INFO**

       The following comes out when a threshold sensor gets an event:
		EVENT
		  Object Type: Sensor
		  Name: <sensor>
		  Operation: Event
		  Threshold: <threshold>
		  High/Low: going-high | going-low
		  Direction: assertion | deassertion
		  %Value: <double>
		  %Raw Value: <integer>
		  %Event
		    **EVENT INFO**

       The following comes out when a sensor is added:
		EVENT
		  Object Type: Sensor
		  Name: <sensor>
		  Operation: Add
		  %**SENSOR INFO**

       The following comes out when a sensor is deleted:
		EVENT
		  Object Type: Sensor
		  Name: <sensor>
		  Operation: Delete

       The following comes out when a sensor is changed:
		EVENT
		  Object Type: Sensor
		  Name: <sensor>
		  Operation: Change
		  %**SENSOR INFO**

       The following comes out when a control gets an event:
		EVENT
		  Object Type: Control
		  Name: <control>
		  Operation: Event
		  Value
		    Number: <integer>
		    Value: <integer>
		  %Event
		    **EVENT INFO**

       The following comes out when a control is added:
		EVENT
		  Object Type: Control
		  Name: <control>
		  Operation: Add
		  %**CONTROL INFO**

       The following comes out when a control is deleted:
		EVENT
		  Object Type: Control
		  Name: <control>
		  Operation: Delete

       The following comes out when a control is changed:
		EVENT
		  Object Type: Control
		  Name: <control>
		  Operation: Change
		  %**CONTROL INFO**

OBJECT INFO
       Many of the command responses and events contain information  about  an
       objects.	 The definitions of this information output is done here.

   **EVENT INFO**
		MC: <mc>
		Record ID: <integer>
		Event type: <integer>
		Timestamp: <integer>
		Data: <data bytes>

   **DOMAIN INFO**
		Type: <domain type>
		GUID: <hex string>
		SEL Rescan Time: <time>
		IPMB Rescan Time: <time>

   **ENTITY INFO**
		Type: unknown | mc | fru | generic
		Present: <bool>
		Presence sensor always there: <bool>
		Hot swappable: <bool>
		%Supports managed hot swap: <bool>
		%Parents
		  Name: <entity>
		  Name: <entity>
		   .
		   .
		%Children
		  Name: <entity>
		  Name: <entity>
		   .
		   .
		%Physical Slot: <integer>
		%Id: <string>
		Entity ID String: <string>

       Note that Parents and Children fields will not be present if the entity
       has no parents or children.  Each entity type except unknown will  have
       its own output info.  These are:

       mc
		Channel: <channel>
		LUN: <lun>
		OEM: <oem field from SDR>
		Slave Address: <ipmb>
		ACPI_system_power_notify_required: <bool>
		ACPI_device_power_notify_required: <bool>
		controller_logs_init_agent_errors: <bool>
		log_init_agent_errors_accessing: <bool>
		global_init: <bool>
		chassis_device: <bool>
		bridge: <bool>
		IPMB_event_generator: <bool>
		IPMB_event_receiver: <bool>
		FRU_inventory_device: <bool>
		SEL_device: <bool>
		SDR_repository_device: <bool>
		sensor_device: <bool>

       fru
		Channel: <channel>
		LUN: <lun>
		OEM: <oem field from SDR>
		Slave Address: <ipmb>
		access_address: <ipmb>
		private_bus_id: <integer>
		device_type: <integer>
		device_modifier: <integer>
		is_logical_fru: <bool>
		fru_device_id: <integer>

       generic
		Channel: <channel>
		LUN: <lun>
		OEM: <oem field from SDR>
		access_address: <ipmb>
		private_bus_id: <integer>
		device_type: <integer>
		device_modifier: <integer>
		slave_address: <ipmb>
		address_span: <integer>

   **MC INFO**
		Active: <bool>
		GUID: <hex string>
		SEL Rescan Time: <integer>
		provides_device_sdrs: <bool>
		device_available: <bool>
		chassis_support: <bool>
		bridge_support: <bool>
		ipmb_event_generator: <bool>
		ipmb_event_receiver: <bool>
		fru_inventory_support: <bool>
		sel_device_support: <bool>
		sdr_repository_support: <bool>
		sensor_device_support: <bool>
		device_id: <ipmb>
		device_revision: <integer>
		fw_revision: <integer>.<integer>
		version: <integer>.<integer>
		manufacturer_id: <integer>
		product_id: <integer>
		aux_fw_revision: <integer> <integer> <integer> <integer>

   *SENSOR INFO**
		LUN: <integer>
		Number: <integer>
		Event Reading Type: <integer>
		Event Reading Type Name: one of:
			 unspecified threshold discrete_usage discrete_state
			 discrete_predictive_failure discrete_limit_exceeded
			 discrete_performance_met discrete_severity discrete_device_presense
			 discrete_device_enable discrete_availability discrete_redundancy
			 discrete_acpi_power
		Type: <integer>
		Type Name: <sensor type (a generic string)>
		%Direction: input | output
		%Event Support: per state | entire sensor | global
		Init Scanning: <bool>
		Init Events: <bool>
		Init Thresholds: <bool>
		Init Hysteresis: <bool>
		Init Type: <bool>
		Init Power Up Events: <bool>
		Init Power Up Scanning: <bool>
		Ignore If No Entity: <bool>
		Auto Rearm: <bool>
		OEM1: <integer>
		Id: <string>

       For threshold sensors, the following exist:
		Threshold Access: none | readable | settable | fixed
		Threshold
		  Name: <threshold>
		  Readable: <bool>
		  Settable: <bool>
		  Supports: going high assertion | going low assertion
			    | going high deassertion | going low deassertion
		 .
		 .
		Hysteresis Support: none | readable | settable | fixed
		%Nominal Reading: <float>
		%Normal Max: <float>
		%Normal Min: <float>
		%Sensor Max: <float>
		%Sensor Min: <float>
		Base Unit: <integer>
		Base Unit Name: <string>
		%Rate Unit: <integer>
		%Rate Unit Name: <string>
		%Modifier Use: / | *
		%Modifier Unit: <integer>
		%Modifier Unit Name: <string>

       For discrete sensors, the following exist:
		Event
		  Offset: <integer>
		  Supports: assertion | deassertion
		 .
		 .

   **CONTROL INFO**
		Type: <control type>
		Generates Events: <bool>
		Settable: <bool>
		Readable: <bool>
		Num Values: <integer>
		Id: <string>

       Controls of type light that are set with settings have the following:
		Set with: settings
		Local Control: <bool>
		Color: <color>
		 .
		 .
       One color is listed for each supported color

       Controls	 of  type light that are set with transitions have the follow‐
       ing:
		Light
		  Number: <integer>
		  Num Values: <integer>
		  Value
		    Number: <integer>
		    Num Transitions: <integer>
		    Transition
		      Number: <integer>
		      Color: <color>
		      Time: <integer>
		     .
		     .
		   .
		   .

       Controls of type identifier have the following:
		Max Length: <integer>

   **FRU INFO**
		Name: <fru>
		record
		  Name: <name>
		  Type: binary | ascii | unicode | integer
		  %Number: <integer>
		  Data: data depending on type
		 .
		 .
		Multi-record
		  Number: <integer>
		  Type: binary | ascii | unicode
		  Data: <data in the above format>
		 .
		 .

   **LANPARM CONFIG**
		support_auth_oem: <bool>
		support_auth_straight: <bool>
		support_auth_md5: <bool>
		support_auth_md2: <bool>
		support_auth_none: <bool>
		ip_addr_source: <integer>
		num_alert_destinations: <integer>
		%ipv4_ttl: <integer>
		%ipv4_flags: <integer>
		%ipv4_precedence: <integer>
		%ipv4_tos: <integer>
		%ip_addr: <ip addr>
		%mac_addr: <mac addr>
		%subnet_mask: <ip addr>
		%primary_rmcp_port <integer>
		%secondary_rmcp_port <integer>
		%bmc_generated_arps: <bool>
		%bmc_generated_garps: <bool>
		%garp_interval: <integer>
		%default_gateway_ip_addr: <ip addr>
		%default_gateway_mac_addr: <mac addr>
		%backup_gateway_ip_addr: <ip addr>
		%backup_gateway_mac_addr: <mac addr>
		community_string: <string>
		User
		  Name: callback
		  enable_auth_oem: <bool>
		  enable_auth_straight: <bool>
		  enable_auth_md5: <bool>
		  enable_auth_md2: <bool>
		  enable_auth_none: <bool>
		User
		  Name: user
		  enable_auth_oem: <bool>
		  enable_auth_straight: <bool>
		  enable_auth_md5: <bool>
		  enable_auth_md2: <bool>
		  enable_auth_none: <bool>
		User
		  Name: operator
		  enable_auth_oem: <bool>
		  enable_auth_straight: <bool>
		  enable_auth_md5: <bool>
		  enable_auth_md2: <bool>
		  enable_auth_none: <bool>
		User
		  Name: admin
		  enable_auth_oem: <bool>
		  enable_auth_straight: <bool>
		  enable_auth_md5: <bool>
		  enable_auth_md2: <bool>
		  enable_auth_none: <bool>
		User
		  Name: oem
		  enable_auth_oem: <bool>
		  enable_auth_straight: <bool>
		  enable_auth_md5: <bool>
		  enable_auth_md2: <bool>
		  enable_auth_none: <bool>
		Alert Destination
		  Number: <integer>
		  alert_ack: <bool>
		  dest_type: <integer>
		  alert_retry_interval: <integer>
		  max_alert_retries: <integer>
		  dest_format: <integer>
		  gw_to_use: <integer>
		  dest_ip_addr: <ip addr>
		  dest_mac_addr: <mac addr>
		 .
		 .

   **PEF CONFIG**
		alert_startup_delay_enabled: <bool>
		startup_delay_enabled: <bool>
		event_messages_enabled: <bool>
		pef_enabled: <bool>
		diagnostic_interrupt_enabled: <bool>
		oem_action_enabled: <bool>
		power_cycle_enabled: <bool>
		reset_enabled: <bool>
		power_down_enabled: <bool>
		alert_enabled: <bool>
		%startup_delay: <integer>
		%alert_startup_delay: <integer>
		guid_enabled: <bool>
		guid_val: <guid>
		num_event_filters: <integer>
		num_alert_policies: <integer>
		num_alert_strings: <integer>
		Event Filter
		  Number: <integer>
		  enable_filter: <bool>
		  filter_type: <integer>
		  diagnostic_interrupt: <bool>
		  oem_action: <bool>
		  power_cycle: <bool>
		  reset: <bool>
		  power_down: <bool>
		  alert: <bool>
		  alert_policy_number: <integer>
		  event_severity: <integer>
		  generator_id_addr: <integer>
		  generator_id_channel_lun: <integer>
		  sensor_type: <integer>
		  sensor_number: <integer>
		  event_trigger: <integer>
		  data1_offset_mask: <integer>
		  data1_mask: <integer>
		  data1_compare1: <integer>
		  data1_compare2: <integer>
		  data2_mask: <integer>
		  data2_compare1: <integer>
		  data2_compare2: <integer>
		  data3_mask: <integer>
		  data3_compare1: <integer>
		  data3_compare2: <integer>
		 .
		 .
		Alert Policy
		  Number: <integer>
		  policy_num: <integer>
		  enabled: <bool>
		  policy: <integer>
		  channel: <integer>
		  destination_selector: <integer>
		  alert_string_event_specific: <bool>
		  alert_string_selector: <integer>
		 .
		 .
		Alert String
		  event_filter: <integer>
		  alert_string_set: <integer>
		  alert_string: <string>
		 .
		 .

   **CONNECTION INFO**
		Active: <bool>
		Up: <bool>
		Port
		  Number: <integer>
		  Info: <info string>
		  Up: <bool>
		 .
		 .

   **PEF INFO**
		MC: <mc>

   **PET INFO**
		MC: <mc>
		Channel: <channel>
		IP Address: <ip address>
		MAC Address: <mac address>
		EFT Selector: <eft selector>
		Policy Number: <policy number>
		APT Selector: <apt selector>
		LAN Dest Selector: <lan dest selector>

   **LANPARM INFO**
		MC: <mc>
		Channel: <integer>

SEE ALSO
       ipmish(1)

KNOWN PROBLEMS
       None

AUTHOR
       Corey Minyard <cminyard@mvista.com>

OpenIPMI			   05/13/03		       ipmi_cmdlang(7)
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