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kernel / include / linux / ipmi.h
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1/* 2 * ipmi.h 3 * 4 * MontaVista IPMI interface 5 * 6 * Author: MontaVista Software, Inc. 7 * Corey Minyard <minyard@mvista.com> 8 * source@mvista.com 9 * 10 * Copyright 2002 MontaVista Software Inc. 11 * 12 * This program is free software; you can redistribute it and/or modify it 13 * under the terms of the GNU General Public License as published by the 14 * Free Software Foundation; either version 2 of the License, or (at your 15 * option) any later version. 16 * 17 * 18 * THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESS OR IMPLIED 19 * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF 20 * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 21 * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 22 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, 23 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS 24 * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND 25 * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR 26 * TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE 27 * USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 28 * 29 * You should have received a copy of the GNU General Public License along 30 * with this program; if not, write to the Free Software Foundation, Inc., 31 * 675 Mass Ave, Cambridge, MA 02139, USA. 32 */ 33 34#ifndef __LINUX_IPMI_H 35#define __LINUX_IPMI_H 36 37#include <linux/ipmi_msgdefs.h> 38 39/* 40 * This file describes an interface to an IPMI driver. You have to 41 * have a fairly good understanding of IPMI to use this, so go read 42 * the specs first before actually trying to do anything. 43 * 44 * With that said, this driver provides a multi-user interface to the 45 * IPMI driver, and it allows multiple IPMI physical interfaces below 46 * the driver. The physical interfaces bind as a lower layer on the 47 * driver. They appear as interfaces to the application using this 48 * interface. 49 * 50 * Multi-user means that multiple applications may use the driver, 51 * send commands, receive responses, etc. The driver keeps track of 52 * commands the user sends and tracks the responses. The responses 53 * will go back to the application that send the command. If the 54 * response doesn't come back in time, the driver will return a 55 * timeout error response to the application. Asynchronous events 56 * from the BMC event queue will go to all users bound to the driver. 57 * The incoming event queue in the BMC will automatically be flushed 58 * if it becomes full and it is queried once a second to see if 59 * anything is in it. Incoming commands to the driver will get 60 * delivered as commands. 61 * 62 * This driver provides two main interfaces: one for in-kernel 63 * applications and another for userland applications. The 64 * capabilities are basically the same for both interface, although 65 * the interfaces are somewhat different. The stuff in the 66 * #ifdef KERNEL below is the in-kernel interface. The userland 67 * interface is defined later in the file. */ 68 69 70 71/* 72 * This is an overlay for all the address types, so it's easy to 73 * determine the actual address type. This is kind of like addresses 74 * work for sockets. 75 */ 76#define IPMI_MAX_ADDR_SIZE 32 77struct ipmi_addr 78{ 79 /* Try to take these from the "Channel Medium Type" table 80 in section 6.5 of the IPMI 1.5 manual. */ 81 int addr_type; 82 short channel; 83 char data[IPMI_MAX_ADDR_SIZE]; 84}; 85 86/* 87 * When the address is not used, the type will be set to this value. 88 * The channel is the BMC's channel number for the channel (usually 89 * 0), or IPMC_BMC_CHANNEL if communicating directly with the BMC. 90 */ 91#define IPMI_SYSTEM_INTERFACE_ADDR_TYPE 0x0c 92struct ipmi_system_interface_addr 93{ 94 int addr_type; 95 short channel; 96 unsigned char lun; 97}; 98 99/* An IPMB Address. */ 100#define IPMI_IPMB_ADDR_TYPE 0x01 101/* Used for broadcast get device id as described in section 17.9 of the 102 IPMI 1.5 manual. */ 103#define IPMI_IPMB_BROADCAST_ADDR_TYPE 0x41 104struct ipmi_ipmb_addr 105{ 106 int addr_type; 107 short channel; 108 unsigned char slave_addr; 109 unsigned char lun; 110}; 111 112/* 113 * A LAN Address. This is an address to/from a LAN interface bridged 114 * by the BMC, not an address actually out on the LAN. 115 * 116 * A concious decision was made here to deviate slightly from the IPMI 117 * spec. We do not use rqSWID and rsSWID like it shows in the 118 * message. Instead, we use remote_SWID and local_SWID. This means 119 * that any message (a request or response) from another device will 120 * always have exactly the same address. If you didn't do this, 121 * requests and responses from the same device would have different 122 * addresses, and that's not too cool. 123 * 124 * In this address, the remote_SWID is always the SWID the remote 125 * message came from, or the SWID we are sending the message to. 126 * local_SWID is always our SWID. Note that having our SWID in the 127 * message is a little weird, but this is required. 128 */ 129#define IPMI_LAN_ADDR_TYPE 0x04 130struct ipmi_lan_addr 131{ 132 int addr_type; 133 short channel; 134 unsigned char privilege; 135 unsigned char session_handle; 136 unsigned char remote_SWID; 137 unsigned char local_SWID; 138 unsigned char lun; 139}; 140 141 142/* 143 * Channel for talking directly with the BMC. When using this 144 * channel, This is for the system interface address type only. FIXME 145 * - is this right, or should we use -1? 146 */ 147#define IPMI_BMC_CHANNEL 0xf 148#define IPMI_NUM_CHANNELS 0x10 149 150 151/* 152 * A raw IPMI message without any addressing. This covers both 153 * commands and responses. The completion code is always the first 154 * byte of data in the response (as the spec shows the messages laid 155 * out). 156 */ 157struct ipmi_msg 158{ 159 unsigned char netfn; 160 unsigned char cmd; 161 unsigned short data_len; 162 unsigned char __user *data; 163}; 164 165struct kernel_ipmi_msg 166{ 167 unsigned char netfn; 168 unsigned char cmd; 169 unsigned short data_len; 170 unsigned char *data; 171}; 172 173/* 174 * Various defines that are useful for IPMI applications. 175 */ 176#define IPMI_INVALID_CMD_COMPLETION_CODE 0xC1 177#define IPMI_TIMEOUT_COMPLETION_CODE 0xC3 178#define IPMI_UNKNOWN_ERR_COMPLETION_CODE 0xff 179 180 181/* 182 * Receive types for messages coming from the receive interface. This 183 * is used for the receive in-kernel interface and in the receive 184 * IOCTL. 185 * 186 * The "IPMI_RESPONSE_RESPNOSE_TYPE" is a little strange sounding, but 187 * it allows you to get the message results when you send a response 188 * message. 189 */ 190#define IPMI_RESPONSE_RECV_TYPE 1 /* A response to a command */ 191#define IPMI_ASYNC_EVENT_RECV_TYPE 2 /* Something from the event queue */ 192#define IPMI_CMD_RECV_TYPE 3 /* A command from somewhere else */ 193#define IPMI_RESPONSE_RESPONSE_TYPE 4 /* The response for 194 a sent response, giving any 195 error status for sending the 196 response. When you send a 197 response message, this will 198 be returned. */ 199/* Note that async events and received commands do not have a completion 200 code as the first byte of the incoming data, unlike a response. */ 201 202 203 204#ifdef __KERNEL__ 205 206/* 207 * The in-kernel interface. 208 */ 209#include <linux/list.h> 210#include <linux/module.h> 211 212#ifdef CONFIG_PROC_FS 213#include <linux/proc_fs.h> 214extern struct proc_dir_entry *proc_ipmi_root; 215#endif /* CONFIG_PROC_FS */ 216 217/* Opaque type for a IPMI message user. One of these is needed to 218 send and receive messages. */ 219typedef struct ipmi_user *ipmi_user_t; 220 221/* 222 * Stuff coming from the receive interface comes as one of these. 223 * They are allocated, the receiver must free them with 224 * ipmi_free_recv_msg() when done with the message. The link is not 225 * used after the message is delivered, so the upper layer may use the 226 * link to build a linked list, if it likes. 227 */ 228struct ipmi_recv_msg 229{ 230 struct list_head link; 231 232 /* The type of message as defined in the "Receive Types" 233 defines above. */ 234 int recv_type; 235 236 ipmi_user_t user; 237 struct ipmi_addr addr; 238 long msgid; 239 struct kernel_ipmi_msg msg; 240 241 /* The user_msg_data is the data supplied when a message was 242 sent, if this is a response to a sent message. If this is 243 not a response to a sent message, then user_msg_data will 244 be NULL. */ 245 void *user_msg_data; 246 247 /* Call this when done with the message. It will presumably free 248 the message and do any other necessary cleanup. */ 249 void (*done)(struct ipmi_recv_msg *msg); 250 251 /* Place-holder for the data, don't make any assumptions about 252 the size or existance of this, since it may change. */ 253 unsigned char msg_data[IPMI_MAX_MSG_LENGTH]; 254}; 255 256/* Allocate and free the receive message. */ 257static inline void ipmi_free_recv_msg(struct ipmi_recv_msg *msg) 258{ 259 msg->done(msg); 260} 261 262struct ipmi_user_hndl 263{ 264 /* Routine type to call when a message needs to be routed to 265 the upper layer. This will be called with some locks held, 266 the only IPMI routines that can be called are ipmi_request 267 and the alloc/free operations. The handler_data is the 268 variable supplied when the receive handler was registered. */ 269 void (*ipmi_recv_hndl)(struct ipmi_recv_msg *msg, 270 void *user_msg_data); 271 272 /* Called when the interface detects a watchdog pre-timeout. If 273 this is NULL, it will be ignored for the user. */ 274 void (*ipmi_watchdog_pretimeout)(void *handler_data); 275}; 276 277/* Create a new user of the IPMI layer on the given interface number. */ 278int ipmi_create_user(unsigned int if_num, 279 struct ipmi_user_hndl *handler, 280 void *handler_data, 281 ipmi_user_t *user); 282 283/* Destroy the given user of the IPMI layer. Note that after this 284 function returns, the system is guaranteed to not call any 285 callbacks for the user. Thus as long as you destroy all the users 286 before you unload a module, you will be safe. And if you destroy 287 the users before you destroy the callback structures, it should be 288 safe, too. */ 289int ipmi_destroy_user(ipmi_user_t user); 290 291/* Get the IPMI version of the BMC we are talking to. */ 292void ipmi_get_version(ipmi_user_t user, 293 unsigned char *major, 294 unsigned char *minor); 295 296/* Set and get the slave address and LUN that we will use for our 297 source messages. Note that this affects the interface, not just 298 this user, so it will affect all users of this interface. This is 299 so some initialization code can come in and do the OEM-specific 300 things it takes to determine your address (if not the BMC) and set 301 it for everyone else. */ 302void ipmi_set_my_address(ipmi_user_t user, 303 unsigned char address); 304unsigned char ipmi_get_my_address(ipmi_user_t user); 305void ipmi_set_my_LUN(ipmi_user_t user, 306 unsigned char LUN); 307unsigned char ipmi_get_my_LUN(ipmi_user_t user); 308 309/* 310 * Like ipmi_request, but lets you specify the number of retries and 311 * the retry time. The retries is the number of times the message 312 * will be resent if no reply is received. If set to -1, the default 313 * value will be used. The retry time is the time in milliseconds 314 * between retries. If set to zero, the default value will be 315 * used. 316 * 317 * Don't use this unless you *really* have to. It's primarily for the 318 * IPMI over LAN converter; since the LAN stuff does its own retries, 319 * it makes no sense to do it here. However, this can be used if you 320 * have unusual requirements. 321 */ 322int ipmi_request_settime(ipmi_user_t user, 323 struct ipmi_addr *addr, 324 long msgid, 325 struct kernel_ipmi_msg *msg, 326 void *user_msg_data, 327 int priority, 328 int max_retries, 329 unsigned int retry_time_ms); 330 331/* 332 * Like ipmi_request, but with messages supplied. This will not 333 * allocate any memory, and the messages may be statically allocated 334 * (just make sure to do the "done" handling on them). Note that this 335 * is primarily for the watchdog timer, since it should be able to 336 * send messages even if no memory is available. This is subject to 337 * change as the system changes, so don't use it unless you REALLY 338 * have to. 339 */ 340int ipmi_request_supply_msgs(ipmi_user_t user, 341 struct ipmi_addr *addr, 342 long msgid, 343 struct kernel_ipmi_msg *msg, 344 void *user_msg_data, 345 void *supplied_smi, 346 struct ipmi_recv_msg *supplied_recv, 347 int priority); 348 349/* 350 * When commands come in to the SMS, the user can register to receive 351 * them. Only one user can be listening on a specific netfn/cmd pair 352 * at a time, you will get an EBUSY error if the command is already 353 * registered. If a command is received that does not have a user 354 * registered, the driver will automatically return the proper 355 * error. 356 */ 357int ipmi_register_for_cmd(ipmi_user_t user, 358 unsigned char netfn, 359 unsigned char cmd); 360int ipmi_unregister_for_cmd(ipmi_user_t user, 361 unsigned char netfn, 362 unsigned char cmd); 363 364/* 365 * Allow run-to-completion mode to be set for the interface of 366 * a specific user. 367 */ 368void ipmi_user_set_run_to_completion(ipmi_user_t user, int val); 369 370/* 371 * When the user is created, it will not receive IPMI events by 372 * default. The user must set this to TRUE to get incoming events. 373 * The first user that sets this to TRUE will receive all events that 374 * have been queued while no one was waiting for events. 375 */ 376int ipmi_set_gets_events(ipmi_user_t user, int val); 377 378/* 379 * Called when a new SMI is registered. This will also be called on 380 * every existing interface when a new watcher is registered with 381 * ipmi_smi_watcher_register(). 382 */ 383struct ipmi_smi_watcher 384{ 385 struct list_head link; 386 387 /* You must set the owner to the current module, if you are in 388 a module (generally just set it to "THIS_MODULE"). */ 389 struct module *owner; 390 391 /* These two are called with read locks held for the interface 392 the watcher list. So you can add and remove users from the 393 IPMI interface, send messages, etc., but you cannot add 394 or remove SMI watchers or SMI interfaces. */ 395 void (*new_smi)(int if_num); 396 void (*smi_gone)(int if_num); 397}; 398 399int ipmi_smi_watcher_register(struct ipmi_smi_watcher *watcher); 400int ipmi_smi_watcher_unregister(struct ipmi_smi_watcher *watcher); 401 402/* The following are various helper functions for dealing with IPMI 403 addresses. */ 404 405/* Return the maximum length of an IPMI address given it's type. */ 406unsigned int ipmi_addr_length(int addr_type); 407 408/* Validate that the given IPMI address is valid. */ 409int ipmi_validate_addr(struct ipmi_addr *addr, int len); 410 411#endif /* __KERNEL__ */ 412 413 414/* 415 * The userland interface 416 */ 417 418/* 419 * The userland interface for the IPMI driver is a standard character 420 * device, with each instance of an interface registered as a minor 421 * number under the major character device. 422 * 423 * The read and write calls do not work, to get messages in and out 424 * requires ioctl calls because of the complexity of the data. select 425 * and poll do work, so you can wait for input using the file 426 * descriptor, you just can use read to get it. 427 * 428 * In general, you send a command down to the interface and receive 429 * responses back. You can use the msgid value to correlate commands 430 * and responses, the driver will take care of figuring out which 431 * incoming messages are for which command and find the proper msgid 432 * value to report. You will only receive reponses for commands you 433 * send. Asynchronous events, however, go to all open users, so you 434 * must be ready to handle these (or ignore them if you don't care). 435 * 436 * The address type depends upon the channel type. When talking 437 * directly to the BMC (IPMC_BMC_CHANNEL), the address is ignored 438 * (IPMI_UNUSED_ADDR_TYPE). When talking to an IPMB channel, you must 439 * supply a valid IPMB address with the addr_type set properly. 440 * 441 * When talking to normal channels, the driver takes care of the 442 * details of formatting and sending messages on that channel. You do 443 * not, for instance, have to format a send command, you just send 444 * whatever command you want to the channel, the driver will create 445 * the send command, automatically issue receive command and get even 446 * commands, and pass those up to the proper user. 447 */ 448 449 450/* The magic IOCTL value for this interface. */ 451#define IPMI_IOC_MAGIC 'i' 452 453 454/* Messages sent to the interface are this format. */ 455struct ipmi_req 456{ 457 unsigned char __user *addr; /* Address to send the message to. */ 458 unsigned int addr_len; 459 460 long msgid; /* The sequence number for the message. This 461 exact value will be reported back in the 462 response to this request if it is a command. 463 If it is a response, this will be used as 464 the sequence value for the response. */ 465 466 struct ipmi_msg msg; 467}; 468/* 469 * Send a message to the interfaces. error values are: 470 * - EFAULT - an address supplied was invalid. 471 * - EINVAL - The address supplied was not valid, or the command 472 * was not allowed. 473 * - EMSGSIZE - The message to was too large. 474 * - ENOMEM - Buffers could not be allocated for the command. 475 */ 476#define IPMICTL_SEND_COMMAND _IOR(IPMI_IOC_MAGIC, 13, \ 477 struct ipmi_req) 478 479/* Messages sent to the interface with timing parameters are this 480 format. */ 481struct ipmi_req_settime 482{ 483 struct ipmi_req req; 484 485 /* See ipmi_request_settime() above for details on these 486 values. */ 487 int retries; 488 unsigned int retry_time_ms; 489}; 490/* 491 * Send a message to the interfaces with timing parameters. error values 492 * are: 493 * - EFAULT - an address supplied was invalid. 494 * - EINVAL - The address supplied was not valid, or the command 495 * was not allowed. 496 * - EMSGSIZE - The message to was too large. 497 * - ENOMEM - Buffers could not be allocated for the command. 498 */ 499#define IPMICTL_SEND_COMMAND_SETTIME _IOR(IPMI_IOC_MAGIC, 21, \ 500 struct ipmi_req_settime) 501 502/* Messages received from the interface are this format. */ 503struct ipmi_recv 504{ 505 int recv_type; /* Is this a command, response or an 506 asyncronous event. */ 507 508 unsigned char __user *addr; /* Address the message was from is put 509 here. The caller must supply the 510 memory. */ 511 unsigned int addr_len; /* The size of the address buffer. 512 The caller supplies the full buffer 513 length, this value is updated to 514 the actual message length when the 515 message is received. */ 516 517 long msgid; /* The sequence number specified in the request 518 if this is a response. If this is a command, 519 this will be the sequence number from the 520 command. */ 521 522 struct ipmi_msg msg; /* The data field must point to a buffer. 523 The data_size field must be set to the 524 size of the message buffer. The 525 caller supplies the full buffer 526 length, this value is updated to the 527 actual message length when the message 528 is received. */ 529}; 530 531/* 532 * Receive a message. error values: 533 * - EAGAIN - no messages in the queue. 534 * - EFAULT - an address supplied was invalid. 535 * - EINVAL - The address supplied was not valid. 536 * - EMSGSIZE - The message to was too large to fit into the message buffer, 537 * the message will be left in the buffer. */ 538#define IPMICTL_RECEIVE_MSG _IOWR(IPMI_IOC_MAGIC, 12, \ 539 struct ipmi_recv) 540 541/* 542 * Like RECEIVE_MSG, but if the message won't fit in the buffer, it 543 * will truncate the contents instead of leaving the data in the 544 * buffer. 545 */ 546#define IPMICTL_RECEIVE_MSG_TRUNC _IOWR(IPMI_IOC_MAGIC, 11, \ 547 struct ipmi_recv) 548 549/* Register to get commands from other entities on this interface. */ 550struct ipmi_cmdspec 551{ 552 unsigned char netfn; 553 unsigned char cmd; 554}; 555 556/* 557 * Register to receive a specific command. error values: 558 * - EFAULT - an address supplied was invalid. 559 * - EBUSY - The netfn/cmd supplied was already in use. 560 * - ENOMEM - could not allocate memory for the entry. 561 */ 562#define IPMICTL_REGISTER_FOR_CMD _IOR(IPMI_IOC_MAGIC, 14, \ 563 struct ipmi_cmdspec) 564/* 565 * Unregister a regsitered command. error values: 566 * - EFAULT - an address supplied was invalid. 567 * - ENOENT - The netfn/cmd was not found registered for this user. 568 */ 569#define IPMICTL_UNREGISTER_FOR_CMD _IOR(IPMI_IOC_MAGIC, 15, \ 570 struct ipmi_cmdspec) 571 572/* 573 * Set whether this interface receives events. Note that the first 574 * user registered for events will get all pending events for the 575 * interface. error values: 576 * - EFAULT - an address supplied was invalid. 577 */ 578#define IPMICTL_SET_GETS_EVENTS_CMD _IOR(IPMI_IOC_MAGIC, 16, int) 579 580/* 581 * Set and get the slave address and LUN that we will use for our 582 * source messages. Note that this affects the interface, not just 583 * this user, so it will affect all users of this interface. This is 584 * so some initialization code can come in and do the OEM-specific 585 * things it takes to determine your address (if not the BMC) and set 586 * it for everyone else. You should probably leave the LUN alone. 587 */ 588#define IPMICTL_SET_MY_ADDRESS_CMD _IOR(IPMI_IOC_MAGIC, 17, unsigned int) 589#define IPMICTL_GET_MY_ADDRESS_CMD _IOR(IPMI_IOC_MAGIC, 18, unsigned int) 590#define IPMICTL_SET_MY_LUN_CMD _IOR(IPMI_IOC_MAGIC, 19, unsigned int) 591#define IPMICTL_GET_MY_LUN_CMD _IOR(IPMI_IOC_MAGIC, 20, unsigned int) 592 593/* 594 * Get/set the default timing values for an interface. You shouldn't 595 * generally mess with these. 596 */ 597struct ipmi_timing_parms 598{ 599 int retries; 600 unsigned int retry_time_ms; 601}; 602#define IPMICTL_SET_TIMING_PARMS_CMD _IOR(IPMI_IOC_MAGIC, 22, \ 603 struct ipmi_timing_parms) 604#define IPMICTL_GET_TIMING_PARMS_CMD _IOR(IPMI_IOC_MAGIC, 23, \ 605 struct ipmi_timing_parms) 606 607#endif /* __LINUX_IPMI_H */