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=====================
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The Linux IPMI Driver
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=====================
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:Author: Corey Minyard <minyard@mvista.com> / <minyard@acm.org>
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The Intelligent Platform Management Interface, or IPMI, is a
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standard for controlling intelligent devices that monitor a system.
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It provides for dynamic discovery of sensors in the system and the
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ability to monitor the sensors and be informed when the sensor's
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values change or go outside certain boundaries. It also has a
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standardized database for field-replaceable units (FRUs) and a watchdog
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timer.
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To use this, you need an interface to an IPMI controller in your
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system (called a Baseboard Management Controller, or BMC) and
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management software that can use the IPMI system.
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This document describes how to use the IPMI driver for Linux. If you
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are not familiar with IPMI itself, see the web site at
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http://www.intel.com/design/servers/ipmi/index.htm. IPMI is a big
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subject and I can't cover it all here!
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Configuration
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-------------
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The Linux IPMI driver is modular, which means you have to pick several
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things to have it work right depending on your hardware. Most of
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these are available in the 'Character Devices' menu then the IPMI
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menu.
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No matter what, you must pick 'IPMI top-level message handler' to use
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IPMI. What you do beyond that depends on your needs and hardware.
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The message handler does not provide any user-level interfaces.
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Kernel code (like the watchdog) can still use it. If you need access
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from userland, you need to select 'Device interface for IPMI' if you
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want access through a device driver.
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The driver interface depends on your hardware. If your system
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properly provides the SMBIOS info for IPMI, the driver will detect it
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and just work. If you have a board with a standard interface (These
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will generally be either "KCS", "SMIC", or "BT", consult your hardware
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manual), choose the 'IPMI SI handler' option. A driver also exists
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for direct I2C access to the IPMI management controller. Some boards
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support this, but it is unknown if it will work on every board. For
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this, choose 'IPMI SMBus handler', but be ready to try to do some
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figuring to see if it will work on your system if the SMBIOS/APCI
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information is wrong or not present. It is fairly safe to have both
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these enabled and let the drivers auto-detect what is present.
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You should generally enable ACPI on your system, as systems with IPMI
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can have ACPI tables describing them.
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If you have a standard interface and the board manufacturer has done
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their job correctly, the IPMI controller should be automatically
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detected (via ACPI or SMBIOS tables) and should just work. Sadly,
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many boards do not have this information. The driver attempts
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standard defaults, but they may not work. If you fall into this
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situation, you need to read the section below named 'The SI Driver' or
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"The SMBus Driver" on how to hand-configure your system.
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IPMI defines a standard watchdog timer. You can enable this with the
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'IPMI Watchdog Timer' config option. If you compile the driver into
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the kernel, then via a kernel command-line option you can have the
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watchdog timer start as soon as it initializes. It also have a lot
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of other options, see the 'Watchdog' section below for more details.
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Note that you can also have the watchdog continue to run if it is
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closed (by default it is disabled on close). Go into the 'Watchdog
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Cards' menu, enable 'Watchdog Timer Support', and enable the option
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'Disable watchdog shutdown on close'.
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IPMI systems can often be powered off using IPMI commands. Select
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'IPMI Poweroff' to do this. The driver will auto-detect if the system
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can be powered off by IPMI. It is safe to enable this even if your
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system doesn't support this option. This works on ATCA systems, the
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Radisys CPI1 card, and any IPMI system that supports standard chassis
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management commands.
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If you want the driver to put an event into the event log on a panic,
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enable the 'Generate a panic event to all BMCs on a panic' option. If
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you want the whole panic string put into the event log using OEM
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events, enable the 'Generate OEM events containing the panic string'
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option.
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Basic Design
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------------
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The Linux IPMI driver is designed to be very modular and flexible, you
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only need to take the pieces you need and you can use it in many
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different ways. Because of that, it's broken into many chunks of
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code. These chunks (by module name) are:
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ipmi_msghandler - This is the central piece of software for the IPMI
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system. It handles all messages, message timing, and responses. The
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IPMI users tie into this, and the IPMI physical interfaces (called
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System Management Interfaces, or SMIs) also tie in here. This
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provides the kernelland interface for IPMI, but does not provide an
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interface for use by application processes.
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ipmi_devintf - This provides a userland IOCTL interface for the IPMI
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driver, each open file for this device ties in to the message handler
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as an IPMI user.
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ipmi_si - A driver for various system interfaces. This supports KCS,
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SMIC, and BT interfaces. Unless you have an SMBus interface or your
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own custom interface, you probably need to use this.
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ipmi_ssif - A driver for accessing BMCs on the SMBus. It uses the
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I2C kernel driver's SMBus interfaces to send and receive IPMI messages
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over the SMBus.
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ipmi_powernv - A driver for access BMCs on POWERNV systems.
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ipmi_watchdog - IPMI requires systems to have a very capable watchdog
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timer. This driver implements the standard Linux watchdog timer
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interface on top of the IPMI message handler.
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ipmi_poweroff - Some systems support the ability to be turned off via
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IPMI commands.
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bt-bmc - This is not part of the main driver, but instead a driver for
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accessing a BMC-side interface of a BT interface. It is used on BMCs
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running Linux to provide an interface to the host.
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These are all individually selectable via configuration options.
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Much documentation for the interface is in the include files. The
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IPMI include files are:
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linux/ipmi.h - Contains the user interface and IOCTL interface for IPMI.
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linux/ipmi_smi.h - Contains the interface for system management interfaces
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(things that interface to IPMI controllers) to use.
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linux/ipmi_msgdefs.h - General definitions for base IPMI messaging.
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Addressing
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----------
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The IPMI addressing works much like IP addresses, you have an overlay
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to handle the different address types. The overlay is::
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struct ipmi_addr
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{
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int addr_type;
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short channel;
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char data[IPMI_MAX_ADDR_SIZE];
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};
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The addr_type determines what the address really is. The driver
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currently understands two different types of addresses.
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"System Interface" addresses are defined as::
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struct ipmi_system_interface_addr
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{
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int addr_type;
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short channel;
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};
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and the type is IPMI_SYSTEM_INTERFACE_ADDR_TYPE. This is used for talking
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straight to the BMC on the current card. The channel must be
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IPMI_BMC_CHANNEL.
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Messages that are destined to go out on the IPMB bus use the
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IPMI_IPMB_ADDR_TYPE address type. The format is::
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struct ipmi_ipmb_addr
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{
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int addr_type;
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short channel;
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unsigned char slave_addr;
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unsigned char lun;
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};
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The "channel" here is generally zero, but some devices support more
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than one channel, it corresponds to the channel as defined in the IPMI
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spec.
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Messages
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--------
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Messages are defined as::
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struct ipmi_msg
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{
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unsigned char netfn;
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unsigned char lun;
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unsigned char cmd;
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unsigned char *data;
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int data_len;
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};
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The driver takes care of adding/stripping the header information. The
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data portion is just the data to be send (do NOT put addressing info
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here) or the response. Note that the completion code of a response is
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the first item in "data", it is not stripped out because that is how
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all the messages are defined in the spec (and thus makes counting the
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offsets a little easier :-).
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When using the IOCTL interface from userland, you must provide a block
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of data for "data", fill it, and set data_len to the length of the
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block of data, even when receiving messages. Otherwise the driver
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will have no place to put the message.
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Messages coming up from the message handler in kernelland will come in
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as::
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struct ipmi_recv_msg
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{
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struct list_head link;
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/* The type of message as defined in the "Receive Types"
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defines above. */
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int recv_type;
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ipmi_user_t *user;
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struct ipmi_addr addr;
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long msgid;
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struct ipmi_msg msg;
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/* Call this when done with the message. It will presumably free
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the message and do any other necessary cleanup. */
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void (*done)(struct ipmi_recv_msg *msg);
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/* Place-holder for the data, don't make any assumptions about
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the size or existence of this, since it may change. */
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unsigned char msg_data[IPMI_MAX_MSG_LENGTH];
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};
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You should look at the receive type and handle the message
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appropriately.
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The Upper Layer Interface (Message Handler)
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-------------------------------------------
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The upper layer of the interface provides the users with a consistent
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view of the IPMI interfaces. It allows multiple SMI interfaces to be
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addressed (because some boards actually have multiple BMCs on them)
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and the user should not have to care what type of SMI is below them.
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Watching For Interfaces
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^^^^^^^^^^^^^^^^^^^^^^^
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When your code comes up, the IPMI driver may or may not have detected
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if IPMI devices exist. So you might have to defer your setup until
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the device is detected, or you might be able to do it immediately.
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To handle this, and to allow for discovery, you register an SMI
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watcher with ipmi_smi_watcher_register() to iterate over interfaces
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and tell you when they come and go.
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Creating the User
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^^^^^^^^^^^^^^^^^
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To use the message handler, you must first create a user using
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ipmi_create_user. The interface number specifies which SMI you want
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to connect to, and you must supply callback functions to be called
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when data comes in. The callback function can run at interrupt level,
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so be careful using the callbacks. This also allows to you pass in a
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piece of data, the handler_data, that will be passed back to you on
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all calls.
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Once you are done, call ipmi_destroy_user() to get rid of the user.
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From userland, opening the device automatically creates a user, and
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closing the device automatically destroys the user.
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Messaging
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^^^^^^^^^
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To send a message from kernel-land, the ipmi_request_settime() call does
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pretty much all message handling. Most of the parameter are
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self-explanatory. However, it takes a "msgid" parameter. This is NOT
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the sequence number of messages. It is simply a long value that is
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passed back when the response for the message is returned. You may
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use it for anything you like.
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Responses come back in the function pointed to by the ipmi_recv_hndl
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field of the "handler" that you passed in to ipmi_create_user().
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Remember again, these may be running at interrupt level. Remember to
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look at the receive type, too.
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From userland, you fill out an ipmi_req_t structure and use the
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IPMICTL_SEND_COMMAND ioctl. For incoming stuff, you can use select()
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or poll() to wait for messages to come in. However, you cannot use
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read() to get them, you must call the IPMICTL_RECEIVE_MSG with the
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ipmi_recv_t structure to actually get the message. Remember that you
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must supply a pointer to a block of data in the msg.data field, and
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you must fill in the msg.data_len field with the size of the data.
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This gives the receiver a place to actually put the message.
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If the message cannot fit into the data you provide, you will get an
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EMSGSIZE error and the driver will leave the data in the receive
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queue. If you want to get it and have it truncate the message, us
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the IPMICTL_RECEIVE_MSG_TRUNC ioctl.
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When you send a command (which is defined by the lowest-order bit of
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the netfn per the IPMI spec) on the IPMB bus, the driver will
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automatically assign the sequence number to the command and save the
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command. If the response is not receive in the IPMI-specified 5
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seconds, it will generate a response automatically saying the command
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timed out. If an unsolicited response comes in (if it was after 5
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seconds, for instance), that response will be ignored.
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In kernelland, after you receive a message and are done with it, you
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MUST call ipmi_free_recv_msg() on it, or you will leak messages. Note
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that you should NEVER mess with the "done" field of a message, that is
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required to properly clean up the message.
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Note that when sending, there is an ipmi_request_supply_msgs() call
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that lets you supply the smi and receive message. This is useful for
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pieces of code that need to work even if the system is out of buffers
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(the watchdog timer uses this, for instance). You supply your own
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buffer and own free routines. This is not recommended for normal use,
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though, since it is tricky to manage your own buffers.
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Events and Incoming Commands
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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The driver takes care of polling for IPMI events and receiving
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commands (commands are messages that are not responses, they are
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commands that other things on the IPMB bus have sent you). To receive
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these, you must register for them, they will not automatically be sent
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to you.
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To receive events, you must call ipmi_set_gets_events() and set the
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"val" to non-zero. Any events that have been received by the driver
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since startup will immediately be delivered to the first user that
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registers for events. After that, if multiple users are registered
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for events, they will all receive all events that come in.
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For receiving commands, you have to individually register commands you
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want to receive. Call ipmi_register_for_cmd() and supply the netfn
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and command name for each command you want to receive. You also
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specify a bitmask of the channels you want to receive the command from
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(or use IPMI_CHAN_ALL for all channels if you don't care). Only one
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user may be registered for each netfn/cmd/channel, but different users
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may register for different commands, or the same command if the
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channel bitmasks do not overlap.
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From userland, equivalent IOCTLs are provided to do these functions.
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The Lower Layer (SMI) Interface
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-------------------------------
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As mentioned before, multiple SMI interfaces may be registered to the
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message handler, each of these is assigned an interface number when
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they register with the message handler. They are generally assigned
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in the order they register, although if an SMI unregisters and then
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another one registers, all bets are off.
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The ipmi_smi.h defines the interface for management interfaces, see
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that for more details.
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The SI Driver
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-------------
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The SI driver allows KCS, BT, and SMIC interfaces to be configured
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in the system. It discovers interfaces through a host of different
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methods, depending on the system.
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You can specify up to four interfaces on the module load line and
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control some module parameters::
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modprobe ipmi_si.o type=<type1>,<type2>....
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ports=<port1>,<port2>... addrs=<addr1>,<addr2>...
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irqs=<irq1>,<irq2>...
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regspacings=<sp1>,<sp2>,... regsizes=<size1>,<size2>,...
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regshifts=<shift1>,<shift2>,...
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slave_addrs=<addr1>,<addr2>,...
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force_kipmid=<enable1>,<enable2>,...
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kipmid_max_busy_us=<ustime1>,<ustime2>,...
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unload_when_empty=[0|1]
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trydmi=[0|1] tryacpi=[0|1]
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tryplatform=[0|1] trypci=[0|1]
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Each of these except try... items is a list, the first item for the
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first interface, second item for the second interface, etc.
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The si_type may be either "kcs", "smic", or "bt". If you leave it blank, it
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defaults to "kcs".
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If you specify addrs as non-zero for an interface, the driver will
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use the memory address given as the address of the device. This
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overrides si_ports.
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If you specify ports as non-zero for an interface, the driver will
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use the I/O port given as the device address.
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If you specify irqs as non-zero for an interface, the driver will
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attempt to use the given interrupt for the device.
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The other try... items disable discovery by their corresponding
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names. These are all enabled by default, set them to zero to disable
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them. The tryplatform disables openfirmware.
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The next three parameters have to do with register layout. The
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registers used by the interfaces may not appear at successive
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locations and they may not be in 8-bit registers. These parameters
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allow the layout of the data in the registers to be more precisely
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specified.
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The regspacings parameter give the number of bytes between successive
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register start addresses. For instance, if the regspacing is set to 4
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and the start address is 0xca2, then the address for the second
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register would be 0xca6. This defaults to 1.
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The regsizes parameter gives the size of a register, in bytes. The
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data used by IPMI is 8-bits wide, but it may be inside a larger
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register. This parameter allows the read and write type to specified.
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It may be 1, 2, 4, or 8. The default is 1.
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Since the register size may be larger than 32 bits, the IPMI data may not
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be in the lower 8 bits. The regshifts parameter give the amount to shift
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the data to get to the actual IPMI data.
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The slave_addrs specifies the IPMI address of the local BMC. This is
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usually 0x20 and the driver defaults to that, but in case it's not, it
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can be specified when the driver starts up.
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The force_ipmid parameter forcefully enables (if set to 1) or disables
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(if set to 0) the kernel IPMI daemon. Normally this is auto-detected
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by the driver, but systems with broken interrupts might need an enable,
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or users that don't want the daemon (don't need the performance, don't
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want the CPU hit) can disable it.
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If unload_when_empty is set to 1, the driver will be unloaded if it
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doesn't find any interfaces or all the interfaces fail to work. The
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default is one. Setting to 0 is useful with the hotmod, but is
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obviously only useful for modules.
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When compiled into the kernel, the parameters can be specified on the
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kernel command line as::
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ipmi_si.type=<type1>,<type2>...
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ipmi_si.ports=<port1>,<port2>... ipmi_si.addrs=<addr1>,<addr2>...
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ipmi_si.irqs=<irq1>,<irq2>...
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ipmi_si.regspacings=<sp1>,<sp2>,...
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ipmi_si.regsizes=<size1>,<size2>,...
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ipmi_si.regshifts=<shift1>,<shift2>,...
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ipmi_si.slave_addrs=<addr1>,<addr2>,...
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ipmi_si.force_kipmid=<enable1>,<enable2>,...
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ipmi_si.kipmid_max_busy_us=<ustime1>,<ustime2>,...
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It works the same as the module parameters of the same names.
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If your IPMI interface does not support interrupts and is a KCS or
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SMIC interface, the IPMI driver will start a kernel thread for the
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interface to help speed things up. This is a low-priority kernel
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thread that constantly polls the IPMI driver while an IPMI operation
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is in progress. The force_kipmid module parameter will all the user to
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force this thread on or off. If you force it off and don't have
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interrupts, the driver will run VERY slowly. Don't blame me,
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these interfaces suck.
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Unfortunately, this thread can use a lot of CPU depending on the
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interface's performance. This can waste a lot of CPU and cause
|
|
various issues with detecting idle CPU and using extra power. To
|
|
avoid this, the kipmid_max_busy_us sets the maximum amount of time, in
|
|
microseconds, that kipmid will spin before sleeping for a tick. This
|
|
value sets a balance between performance and CPU waste and needs to be
|
|
tuned to your needs. Maybe, someday, auto-tuning will be added, but
|
|
that's not a simple thing and even the auto-tuning would need to be
|
|
tuned to the user's desired performance.
|
|
|
|
The driver supports a hot add and remove of interfaces. This way,
|
|
interfaces can be added or removed after the kernel is up and running.
|
|
This is done using /sys/modules/ipmi_si/parameters/hotmod, which is a
|
|
write-only parameter. You write a string to this interface. The string
|
|
has the format::
|
|
|
|
<op1>[:op2[:op3...]]
|
|
|
|
The "op"s are::
|
|
|
|
add|remove,kcs|bt|smic,mem|i/o,<address>[,<opt1>[,<opt2>[,...]]]
|
|
|
|
You can specify more than one interface on the line. The "opt"s are::
|
|
|
|
rsp=<regspacing>
|
|
rsi=<regsize>
|
|
rsh=<regshift>
|
|
irq=<irq>
|
|
ipmb=<ipmb slave addr>
|
|
|
|
and these have the same meanings as discussed above. Note that you
|
|
can also use this on the kernel command line for a more compact format
|
|
for specifying an interface. Note that when removing an interface,
|
|
only the first three parameters (si type, address type, and address)
|
|
are used for the comparison. Any options are ignored for removing.
|
|
|
|
The SMBus Driver (SSIF)
|
|
-----------------------
|
|
|
|
The SMBus driver allows up to 4 SMBus devices to be configured in the
|
|
system. By default, the driver will only register with something it
|
|
finds in DMI or ACPI tables. You can change this
|
|
at module load time (for a module) with::
|
|
|
|
modprobe ipmi_ssif.o
|
|
addr=<i2caddr1>[,<i2caddr2>[,...]]
|
|
adapter=<adapter1>[,<adapter2>[...]]
|
|
dbg=<flags1>,<flags2>...
|
|
slave_addrs=<addr1>,<addr2>,...
|
|
tryacpi=[0|1] trydmi=[0|1]
|
|
[dbg_probe=1]
|
|
|
|
The addresses are normal I2C addresses. The adapter is the string
|
|
name of the adapter, as shown in /sys/class/i2c-adapter/i2c-<n>/name.
|
|
It is *NOT* i2c-<n> itself. Also, the comparison is done ignoring
|
|
spaces, so if the name is "This is an I2C chip" you can say
|
|
adapter_name=ThisisanI2cchip. This is because it's hard to pass in
|
|
spaces in kernel parameters.
|
|
|
|
The debug flags are bit flags for each BMC found, they are:
|
|
IPMI messages: 1, driver state: 2, timing: 4, I2C probe: 8
|
|
|
|
The tryxxx parameters can be used to disable detecting interfaces
|
|
from various sources.
|
|
|
|
Setting dbg_probe to 1 will enable debugging of the probing and
|
|
detection process for BMCs on the SMBusses.
|
|
|
|
The slave_addrs specifies the IPMI address of the local BMC. This is
|
|
usually 0x20 and the driver defaults to that, but in case it's not, it
|
|
can be specified when the driver starts up.
|
|
|
|
Discovering the IPMI compliant BMC on the SMBus can cause devices on
|
|
the I2C bus to fail. The SMBus driver writes a "Get Device ID" IPMI
|
|
message as a block write to the I2C bus and waits for a response.
|
|
This action can be detrimental to some I2C devices. It is highly
|
|
recommended that the known I2C address be given to the SMBus driver in
|
|
the smb_addr parameter unless you have DMI or ACPI data to tell the
|
|
driver what to use.
|
|
|
|
When compiled into the kernel, the addresses can be specified on the
|
|
kernel command line as::
|
|
|
|
ipmb_ssif.addr=<i2caddr1>[,<i2caddr2>[...]]
|
|
ipmi_ssif.adapter=<adapter1>[,<adapter2>[...]]
|
|
ipmi_ssif.dbg=<flags1>[,<flags2>[...]]
|
|
ipmi_ssif.dbg_probe=1
|
|
ipmi_ssif.slave_addrs=<addr1>[,<addr2>[...]]
|
|
ipmi_ssif.tryacpi=[0|1] ipmi_ssif.trydmi=[0|1]
|
|
|
|
These are the same options as on the module command line.
|
|
|
|
The I2C driver does not support non-blocking access or polling, so
|
|
this driver cannod to IPMI panic events, extend the watchdog at panic
|
|
time, or other panic-related IPMI functions without special kernel
|
|
patches and driver modifications. You can get those at the openipmi
|
|
web page.
|
|
|
|
The driver supports a hot add and remove of interfaces through the I2C
|
|
sysfs interface.
|
|
|
|
Other Pieces
|
|
------------
|
|
|
|
Get the detailed info related with the IPMI device
|
|
--------------------------------------------------
|
|
|
|
Some users need more detailed information about a device, like where
|
|
the address came from or the raw base device for the IPMI interface.
|
|
You can use the IPMI smi_watcher to catch the IPMI interfaces as they
|
|
come or go, and to grab the information, you can use the function
|
|
ipmi_get_smi_info(), which returns the following structure::
|
|
|
|
struct ipmi_smi_info {
|
|
enum ipmi_addr_src addr_src;
|
|
struct device *dev;
|
|
union {
|
|
struct {
|
|
void *acpi_handle;
|
|
} acpi_info;
|
|
} addr_info;
|
|
};
|
|
|
|
Currently special info for only for SI_ACPI address sources is
|
|
returned. Others may be added as necessary.
|
|
|
|
Note that the dev pointer is included in the above structure, and
|
|
assuming ipmi_smi_get_info returns success, you must call put_device
|
|
on the dev pointer.
|
|
|
|
|
|
Watchdog
|
|
--------
|
|
|
|
A watchdog timer is provided that implements the Linux-standard
|
|
watchdog timer interface. It has three module parameters that can be
|
|
used to control it::
|
|
|
|
modprobe ipmi_watchdog timeout=<t> pretimeout=<t> action=<action type>
|
|
preaction=<preaction type> preop=<preop type> start_now=x
|
|
nowayout=x ifnum_to_use=n panic_wdt_timeout=<t>
|
|
|
|
ifnum_to_use specifies which interface the watchdog timer should use.
|
|
The default is -1, which means to pick the first one registered.
|
|
|
|
The timeout is the number of seconds to the action, and the pretimeout
|
|
is the amount of seconds before the reset that the pre-timeout panic will
|
|
occur (if pretimeout is zero, then pretimeout will not be enabled). Note
|
|
that the pretimeout is the time before the final timeout. So if the
|
|
timeout is 50 seconds and the pretimeout is 10 seconds, then the pretimeout
|
|
will occur in 40 second (10 seconds before the timeout). The panic_wdt_timeout
|
|
is the value of timeout which is set on kernel panic, in order to let actions
|
|
such as kdump to occur during panic.
|
|
|
|
The action may be "reset", "power_cycle", or "power_off", and
|
|
specifies what to do when the timer times out, and defaults to
|
|
"reset".
|
|
|
|
The preaction may be "pre_smi" for an indication through the SMI
|
|
interface, "pre_int" for an indication through the SMI with an
|
|
interrupts, and "pre_nmi" for a NMI on a preaction. This is how
|
|
the driver is informed of the pretimeout.
|
|
|
|
The preop may be set to "preop_none" for no operation on a pretimeout,
|
|
"preop_panic" to set the preoperation to panic, or "preop_give_data"
|
|
to provide data to read from the watchdog device when the pretimeout
|
|
occurs. A "pre_nmi" setting CANNOT be used with "preop_give_data"
|
|
because you can't do data operations from an NMI.
|
|
|
|
When preop is set to "preop_give_data", one byte comes ready to read
|
|
on the device when the pretimeout occurs. Select and fasync work on
|
|
the device, as well.
|
|
|
|
If start_now is set to 1, the watchdog timer will start running as
|
|
soon as the driver is loaded.
|
|
|
|
If nowayout is set to 1, the watchdog timer will not stop when the
|
|
watchdog device is closed. The default value of nowayout is true
|
|
if the CONFIG_WATCHDOG_NOWAYOUT option is enabled, or false if not.
|
|
|
|
When compiled into the kernel, the kernel command line is available
|
|
for configuring the watchdog::
|
|
|
|
ipmi_watchdog.timeout=<t> ipmi_watchdog.pretimeout=<t>
|
|
ipmi_watchdog.action=<action type>
|
|
ipmi_watchdog.preaction=<preaction type>
|
|
ipmi_watchdog.preop=<preop type>
|
|
ipmi_watchdog.start_now=x
|
|
ipmi_watchdog.nowayout=x
|
|
ipmi_watchdog.panic_wdt_timeout=<t>
|
|
|
|
The options are the same as the module parameter options.
|
|
|
|
The watchdog will panic and start a 120 second reset timeout if it
|
|
gets a pre-action. During a panic or a reboot, the watchdog will
|
|
start a 120 timer if it is running to make sure the reboot occurs.
|
|
|
|
Note that if you use the NMI preaction for the watchdog, you MUST NOT
|
|
use the nmi watchdog. There is no reasonable way to tell if an NMI
|
|
comes from the IPMI controller, so it must assume that if it gets an
|
|
otherwise unhandled NMI, it must be from IPMI and it will panic
|
|
immediately.
|
|
|
|
Once you open the watchdog timer, you must write a 'V' character to the
|
|
device to close it, or the timer will not stop. This is a new semantic
|
|
for the driver, but makes it consistent with the rest of the watchdog
|
|
drivers in Linux.
|
|
|
|
|
|
Panic Timeouts
|
|
--------------
|
|
|
|
The OpenIPMI driver supports the ability to put semi-custom and custom
|
|
events in the system event log if a panic occurs. if you enable the
|
|
'Generate a panic event to all BMCs on a panic' option, you will get
|
|
one event on a panic in a standard IPMI event format. If you enable
|
|
the 'Generate OEM events containing the panic string' option, you will
|
|
also get a bunch of OEM events holding the panic string.
|
|
|
|
|
|
The field settings of the events are:
|
|
|
|
* Generator ID: 0x21 (kernel)
|
|
* EvM Rev: 0x03 (this event is formatting in IPMI 1.0 format)
|
|
* Sensor Type: 0x20 (OS critical stop sensor)
|
|
* Sensor #: The first byte of the panic string (0 if no panic string)
|
|
* Event Dir | Event Type: 0x6f (Assertion, sensor-specific event info)
|
|
* Event Data 1: 0xa1 (Runtime stop in OEM bytes 2 and 3)
|
|
* Event data 2: second byte of panic string
|
|
* Event data 3: third byte of panic string
|
|
|
|
See the IPMI spec for the details of the event layout. This event is
|
|
always sent to the local management controller. It will handle routing
|
|
the message to the right place
|
|
|
|
Other OEM events have the following format:
|
|
|
|
* Record ID (bytes 0-1): Set by the SEL.
|
|
* Record type (byte 2): 0xf0 (OEM non-timestamped)
|
|
* byte 3: The slave address of the card saving the panic
|
|
* byte 4: A sequence number (starting at zero)
|
|
The rest of the bytes (11 bytes) are the panic string. If the panic string
|
|
is longer than 11 bytes, multiple messages will be sent with increasing
|
|
sequence numbers.
|
|
|
|
Because you cannot send OEM events using the standard interface, this
|
|
function will attempt to find an SEL and add the events there. It
|
|
will first query the capabilities of the local management controller.
|
|
If it has an SEL, then they will be stored in the SEL of the local
|
|
management controller. If not, and the local management controller is
|
|
an event generator, the event receiver from the local management
|
|
controller will be queried and the events sent to the SEL on that
|
|
device. Otherwise, the events go nowhere since there is nowhere to
|
|
send them.
|
|
|
|
|
|
Poweroff
|
|
--------
|
|
|
|
If the poweroff capability is selected, the IPMI driver will install
|
|
a shutdown function into the standard poweroff function pointer. This
|
|
is in the ipmi_poweroff module. When the system requests a powerdown,
|
|
it will send the proper IPMI commands to do this. This is supported on
|
|
several platforms.
|
|
|
|
There is a module parameter named "poweroff_powercycle" that may
|
|
either be zero (do a power down) or non-zero (do a power cycle, power
|
|
the system off, then power it on in a few seconds). Setting
|
|
ipmi_poweroff.poweroff_control=x will do the same thing on the kernel
|
|
command line. The parameter is also available via the proc filesystem
|
|
in /proc/sys/dev/ipmi/poweroff_powercycle. Note that if the system
|
|
does not support power cycling, it will always do the power off.
|
|
|
|
The "ifnum_to_use" parameter specifies which interface the poweroff
|
|
code should use. The default is -1, which means to pick the first one
|
|
registered.
|
|
|
|
Note that if you have ACPI enabled, the system will prefer using ACPI to
|
|
power off.
|