1 /* 2 * ipmi_si.c 3 * 4 * The interface to the IPMI driver for the system interfaces (KCS, SMIC, 5 * BT). 6 * 7 * Author: MontaVista Software, Inc. 8 * Corey Minyard <minyard@mvista.com> 9 * source@mvista.com 10 * 11 * Copyright 2002 MontaVista Software Inc. 12 * 13 * This program is free software; you can redistribute it and/or modify it 14 * under the terms of the GNU General Public License as published by the 15 * Free Software Foundation; either version 2 of the License, or (at your 16 * option) any later version. 17 * 18 * 19 * THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESS OR IMPLIED 20 * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF 21 * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 22 * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 23 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, 24 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS 25 * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND 26 * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR 27 * TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE 28 * USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 29 * 30 * You should have received a copy of the GNU General Public License along 31 * with this program; if not, write to the Free Software Foundation, Inc., 32 * 675 Mass Ave, Cambridge, MA 02139, USA. 33 */ 34 35 /* 36 * This file holds the "policy" for the interface to the SMI state 37 * machine. It does the configuration, handles timers and interrupts, 38 * and drives the real SMI state machine. 39 */ 40 41 #include <linux/config.h> 42 #include <linux/module.h> 43 #include <linux/moduleparam.h> 44 #include <asm/system.h> 45 #include <linux/sched.h> 46 #include <linux/timer.h> 47 #include <linux/errno.h> 48 #include <linux/spinlock.h> 49 #include <linux/slab.h> 50 #include <linux/delay.h> 51 #include <linux/list.h> 52 #include <linux/pci.h> 53 #include <linux/ioport.h> 54 #include <linux/notifier.h> 55 #include <linux/kthread.h> 56 #include <asm/irq.h> 57 #ifdef CONFIG_HIGH_RES_TIMERS 58 #include <linux/hrtime.h> 59 # if defined(schedule_next_int) 60 /* Old high-res timer code, do translations. */ 61 # define get_arch_cycles(a) quick_update_jiffies_sub(a) 62 # define arch_cycles_per_jiffy cycles_per_jiffies 63 # endif 64 static inline void add_usec_to_timer(struct timer_list *t, long v) 65 { 66 t->arch_cycle_expires += nsec_to_arch_cycle(v * 1000); 67 while (t->arch_cycle_expires >= arch_cycles_per_jiffy) 68 { 69 t->expires++; 70 t->arch_cycle_expires -= arch_cycles_per_jiffy; 71 } 72 } 73 #endif 74 #include <linux/interrupt.h> 75 #include <linux/rcupdate.h> 76 #include <linux/ipmi_smi.h> 77 #include <asm/io.h> 78 #include "ipmi_si_sm.h" 79 #include <linux/init.h> 80 #include <linux/dmi.h> 81 82 /* Measure times between events in the driver. */ 83 #undef DEBUG_TIMING 84 85 /* Call every 10 ms. */ 86 #define SI_TIMEOUT_TIME_USEC 10000 87 #define SI_USEC_PER_JIFFY (1000000/HZ) 88 #define SI_TIMEOUT_JIFFIES (SI_TIMEOUT_TIME_USEC/SI_USEC_PER_JIFFY) 89 #define SI_SHORT_TIMEOUT_USEC 250 /* .25ms when the SM request a 90 short timeout */ 91 92 enum si_intf_state { 93 SI_NORMAL, 94 SI_GETTING_FLAGS, 95 SI_GETTING_EVENTS, 96 SI_CLEARING_FLAGS, 97 SI_CLEARING_FLAGS_THEN_SET_IRQ, 98 SI_GETTING_MESSAGES, 99 SI_ENABLE_INTERRUPTS1, 100 SI_ENABLE_INTERRUPTS2 101 /* FIXME - add watchdog stuff. */ 102 }; 103 104 /* Some BT-specific defines we need here. */ 105 #define IPMI_BT_INTMASK_REG 2 106 #define IPMI_BT_INTMASK_CLEAR_IRQ_BIT 2 107 #define IPMI_BT_INTMASK_ENABLE_IRQ_BIT 1 108 109 enum si_type { 110 SI_KCS, SI_SMIC, SI_BT 111 }; 112 113 struct ipmi_device_id { 114 unsigned char device_id; 115 unsigned char device_revision; 116 unsigned char firmware_revision_1; 117 unsigned char firmware_revision_2; 118 unsigned char ipmi_version; 119 unsigned char additional_device_support; 120 unsigned char manufacturer_id[3]; 121 unsigned char product_id[2]; 122 unsigned char aux_firmware_revision[4]; 123 } __attribute__((packed)); 124 125 #define ipmi_version_major(v) ((v)->ipmi_version & 0xf) 126 #define ipmi_version_minor(v) ((v)->ipmi_version >> 4) 127 128 struct smi_info 129 { 130 int intf_num; 131 ipmi_smi_t intf; 132 struct si_sm_data *si_sm; 133 struct si_sm_handlers *handlers; 134 enum si_type si_type; 135 spinlock_t si_lock; 136 spinlock_t msg_lock; 137 struct list_head xmit_msgs; 138 struct list_head hp_xmit_msgs; 139 struct ipmi_smi_msg *curr_msg; 140 enum si_intf_state si_state; 141 142 /* Used to handle the various types of I/O that can occur with 143 IPMI */ 144 struct si_sm_io io; 145 int (*io_setup)(struct smi_info *info); 146 void (*io_cleanup)(struct smi_info *info); 147 int (*irq_setup)(struct smi_info *info); 148 void (*irq_cleanup)(struct smi_info *info); 149 unsigned int io_size; 150 151 /* Per-OEM handler, called from handle_flags(). 152 Returns 1 when handle_flags() needs to be re-run 153 or 0 indicating it set si_state itself. 154 */ 155 int (*oem_data_avail_handler)(struct smi_info *smi_info); 156 157 /* Flags from the last GET_MSG_FLAGS command, used when an ATTN 158 is set to hold the flags until we are done handling everything 159 from the flags. */ 160 #define RECEIVE_MSG_AVAIL 0x01 161 #define EVENT_MSG_BUFFER_FULL 0x02 162 #define WDT_PRE_TIMEOUT_INT 0x08 163 #define OEM0_DATA_AVAIL 0x20 164 #define OEM1_DATA_AVAIL 0x40 165 #define OEM2_DATA_AVAIL 0x80 166 #define OEM_DATA_AVAIL (OEM0_DATA_AVAIL | \ 167 OEM1_DATA_AVAIL | \ 168 OEM2_DATA_AVAIL) 169 unsigned char msg_flags; 170 171 /* If set to true, this will request events the next time the 172 state machine is idle. */ 173 atomic_t req_events; 174 175 /* If true, run the state machine to completion on every send 176 call. Generally used after a panic to make sure stuff goes 177 out. */ 178 int run_to_completion; 179 180 /* The I/O port of an SI interface. */ 181 int port; 182 183 /* The space between start addresses of the two ports. For 184 instance, if the first port is 0xca2 and the spacing is 4, then 185 the second port is 0xca6. */ 186 unsigned int spacing; 187 188 /* zero if no irq; */ 189 int irq; 190 191 /* The timer for this si. */ 192 struct timer_list si_timer; 193 194 /* The time (in jiffies) the last timeout occurred at. */ 195 unsigned long last_timeout_jiffies; 196 197 /* Used to gracefully stop the timer without race conditions. */ 198 atomic_t stop_operation; 199 200 /* The driver will disable interrupts when it gets into a 201 situation where it cannot handle messages due to lack of 202 memory. Once that situation clears up, it will re-enable 203 interrupts. */ 204 int interrupt_disabled; 205 206 struct ipmi_device_id device_id; 207 208 /* Slave address, could be reported from DMI. */ 209 unsigned char slave_addr; 210 211 /* Counters and things for the proc filesystem. */ 212 spinlock_t count_lock; 213 unsigned long short_timeouts; 214 unsigned long long_timeouts; 215 unsigned long timeout_restarts; 216 unsigned long idles; 217 unsigned long interrupts; 218 unsigned long attentions; 219 unsigned long flag_fetches; 220 unsigned long hosed_count; 221 unsigned long complete_transactions; 222 unsigned long events; 223 unsigned long watchdog_pretimeouts; 224 unsigned long incoming_messages; 225 226 struct task_struct *thread; 227 }; 228 229 static struct notifier_block *xaction_notifier_list; 230 static int register_xaction_notifier(struct notifier_block * nb) 231 { 232 return notifier_chain_register(&xaction_notifier_list, nb); 233 } 234 235 static void si_restart_short_timer(struct smi_info *smi_info); 236 237 static void deliver_recv_msg(struct smi_info *smi_info, 238 struct ipmi_smi_msg *msg) 239 { 240 /* Deliver the message to the upper layer with the lock 241 released. */ 242 spin_unlock(&(smi_info->si_lock)); 243 ipmi_smi_msg_received(smi_info->intf, msg); 244 spin_lock(&(smi_info->si_lock)); 245 } 246 247 static void return_hosed_msg(struct smi_info *smi_info) 248 { 249 struct ipmi_smi_msg *msg = smi_info->curr_msg; 250 251 /* Make it a reponse */ 252 msg->rsp[0] = msg->data[0] | 4; 253 msg->rsp[1] = msg->data[1]; 254 msg->rsp[2] = 0xFF; /* Unknown error. */ 255 msg->rsp_size = 3; 256 257 smi_info->curr_msg = NULL; 258 deliver_recv_msg(smi_info, msg); 259 } 260 261 static enum si_sm_result start_next_msg(struct smi_info *smi_info) 262 { 263 int rv; 264 struct list_head *entry = NULL; 265 #ifdef DEBUG_TIMING 266 struct timeval t; 267 #endif 268 269 /* No need to save flags, we aleady have interrupts off and we 270 already hold the SMI lock. */ 271 spin_lock(&(smi_info->msg_lock)); 272 273 /* Pick the high priority queue first. */ 274 if (! list_empty(&(smi_info->hp_xmit_msgs))) { 275 entry = smi_info->hp_xmit_msgs.next; 276 } else if (! list_empty(&(smi_info->xmit_msgs))) { 277 entry = smi_info->xmit_msgs.next; 278 } 279 280 if (! entry) { 281 smi_info->curr_msg = NULL; 282 rv = SI_SM_IDLE; 283 } else { 284 int err; 285 286 list_del(entry); 287 smi_info->curr_msg = list_entry(entry, 288 struct ipmi_smi_msg, 289 link); 290 #ifdef DEBUG_TIMING 291 do_gettimeofday(&t); 292 printk("**Start2: %d.%9.9d\n", t.tv_sec, t.tv_usec); 293 #endif 294 err = notifier_call_chain(&xaction_notifier_list, 0, smi_info); 295 if (err & NOTIFY_STOP_MASK) { 296 rv = SI_SM_CALL_WITHOUT_DELAY; 297 goto out; 298 } 299 err = smi_info->handlers->start_transaction( 300 smi_info->si_sm, 301 smi_info->curr_msg->data, 302 smi_info->curr_msg->data_size); 303 if (err) { 304 return_hosed_msg(smi_info); 305 } 306 307 rv = SI_SM_CALL_WITHOUT_DELAY; 308 } 309 out: 310 spin_unlock(&(smi_info->msg_lock)); 311 312 return rv; 313 } 314 315 static void start_enable_irq(struct smi_info *smi_info) 316 { 317 unsigned char msg[2]; 318 319 /* If we are enabling interrupts, we have to tell the 320 BMC to use them. */ 321 msg[0] = (IPMI_NETFN_APP_REQUEST << 2); 322 msg[1] = IPMI_GET_BMC_GLOBAL_ENABLES_CMD; 323 324 smi_info->handlers->start_transaction(smi_info->si_sm, msg, 2); 325 smi_info->si_state = SI_ENABLE_INTERRUPTS1; 326 } 327 328 static void start_clear_flags(struct smi_info *smi_info) 329 { 330 unsigned char msg[3]; 331 332 /* Make sure the watchdog pre-timeout flag is not set at startup. */ 333 msg[0] = (IPMI_NETFN_APP_REQUEST << 2); 334 msg[1] = IPMI_CLEAR_MSG_FLAGS_CMD; 335 msg[2] = WDT_PRE_TIMEOUT_INT; 336 337 smi_info->handlers->start_transaction(smi_info->si_sm, msg, 3); 338 smi_info->si_state = SI_CLEARING_FLAGS; 339 } 340 341 /* When we have a situtaion where we run out of memory and cannot 342 allocate messages, we just leave them in the BMC and run the system 343 polled until we can allocate some memory. Once we have some 344 memory, we will re-enable the interrupt. */ 345 static inline void disable_si_irq(struct smi_info *smi_info) 346 { 347 if ((smi_info->irq) && (! smi_info->interrupt_disabled)) { 348 disable_irq_nosync(smi_info->irq); 349 smi_info->interrupt_disabled = 1; 350 } 351 } 352 353 static inline void enable_si_irq(struct smi_info *smi_info) 354 { 355 if ((smi_info->irq) && (smi_info->interrupt_disabled)) { 356 enable_irq(smi_info->irq); 357 smi_info->interrupt_disabled = 0; 358 } 359 } 360 361 static void handle_flags(struct smi_info *smi_info) 362 { 363 retry: 364 if (smi_info->msg_flags & WDT_PRE_TIMEOUT_INT) { 365 /* Watchdog pre-timeout */ 366 spin_lock(&smi_info->count_lock); 367 smi_info->watchdog_pretimeouts++; 368 spin_unlock(&smi_info->count_lock); 369 370 start_clear_flags(smi_info); 371 smi_info->msg_flags &= ~WDT_PRE_TIMEOUT_INT; 372 spin_unlock(&(smi_info->si_lock)); 373 ipmi_smi_watchdog_pretimeout(smi_info->intf); 374 spin_lock(&(smi_info->si_lock)); 375 } else if (smi_info->msg_flags & RECEIVE_MSG_AVAIL) { 376 /* Messages available. */ 377 smi_info->curr_msg = ipmi_alloc_smi_msg(); 378 if (! smi_info->curr_msg) { 379 disable_si_irq(smi_info); 380 smi_info->si_state = SI_NORMAL; 381 return; 382 } 383 enable_si_irq(smi_info); 384 385 smi_info->curr_msg->data[0] = (IPMI_NETFN_APP_REQUEST << 2); 386 smi_info->curr_msg->data[1] = IPMI_GET_MSG_CMD; 387 smi_info->curr_msg->data_size = 2; 388 389 smi_info->handlers->start_transaction( 390 smi_info->si_sm, 391 smi_info->curr_msg->data, 392 smi_info->curr_msg->data_size); 393 smi_info->si_state = SI_GETTING_MESSAGES; 394 } else if (smi_info->msg_flags & EVENT_MSG_BUFFER_FULL) { 395 /* Events available. */ 396 smi_info->curr_msg = ipmi_alloc_smi_msg(); 397 if (! smi_info->curr_msg) { 398 disable_si_irq(smi_info); 399 smi_info->si_state = SI_NORMAL; 400 return; 401 } 402 enable_si_irq(smi_info); 403 404 smi_info->curr_msg->data[0] = (IPMI_NETFN_APP_REQUEST << 2); 405 smi_info->curr_msg->data[1] = IPMI_READ_EVENT_MSG_BUFFER_CMD; 406 smi_info->curr_msg->data_size = 2; 407 408 smi_info->handlers->start_transaction( 409 smi_info->si_sm, 410 smi_info->curr_msg->data, 411 smi_info->curr_msg->data_size); 412 smi_info->si_state = SI_GETTING_EVENTS; 413 } else if (smi_info->msg_flags & OEM_DATA_AVAIL) { 414 if (smi_info->oem_data_avail_handler) 415 if (smi_info->oem_data_avail_handler(smi_info)) 416 goto retry; 417 } else { 418 smi_info->si_state = SI_NORMAL; 419 } 420 } 421 422 static void handle_transaction_done(struct smi_info *smi_info) 423 { 424 struct ipmi_smi_msg *msg; 425 #ifdef DEBUG_TIMING 426 struct timeval t; 427 428 do_gettimeofday(&t); 429 printk("**Done: %d.%9.9d\n", t.tv_sec, t.tv_usec); 430 #endif 431 switch (smi_info->si_state) { 432 case SI_NORMAL: 433 if (! smi_info->curr_msg) 434 break; 435 436 smi_info->curr_msg->rsp_size 437 = smi_info->handlers->get_result( 438 smi_info->si_sm, 439 smi_info->curr_msg->rsp, 440 IPMI_MAX_MSG_LENGTH); 441 442 /* Do this here becase deliver_recv_msg() releases the 443 lock, and a new message can be put in during the 444 time the lock is released. */ 445 msg = smi_info->curr_msg; 446 smi_info->curr_msg = NULL; 447 deliver_recv_msg(smi_info, msg); 448 break; 449 450 case SI_GETTING_FLAGS: 451 { 452 unsigned char msg[4]; 453 unsigned int len; 454 455 /* We got the flags from the SMI, now handle them. */ 456 len = smi_info->handlers->get_result(smi_info->si_sm, msg, 4); 457 if (msg[2] != 0) { 458 /* Error fetching flags, just give up for 459 now. */ 460 smi_info->si_state = SI_NORMAL; 461 } else if (len < 4) { 462 /* Hmm, no flags. That's technically illegal, but 463 don't use uninitialized data. */ 464 smi_info->si_state = SI_NORMAL; 465 } else { 466 smi_info->msg_flags = msg[3]; 467 handle_flags(smi_info); 468 } 469 break; 470 } 471 472 case SI_CLEARING_FLAGS: 473 case SI_CLEARING_FLAGS_THEN_SET_IRQ: 474 { 475 unsigned char msg[3]; 476 477 /* We cleared the flags. */ 478 smi_info->handlers->get_result(smi_info->si_sm, msg, 3); 479 if (msg[2] != 0) { 480 /* Error clearing flags */ 481 printk(KERN_WARNING 482 "ipmi_si: Error clearing flags: %2.2x\n", 483 msg[2]); 484 } 485 if (smi_info->si_state == SI_CLEARING_FLAGS_THEN_SET_IRQ) 486 start_enable_irq(smi_info); 487 else 488 smi_info->si_state = SI_NORMAL; 489 break; 490 } 491 492 case SI_GETTING_EVENTS: 493 { 494 smi_info->curr_msg->rsp_size 495 = smi_info->handlers->get_result( 496 smi_info->si_sm, 497 smi_info->curr_msg->rsp, 498 IPMI_MAX_MSG_LENGTH); 499 500 /* Do this here becase deliver_recv_msg() releases the 501 lock, and a new message can be put in during the 502 time the lock is released. */ 503 msg = smi_info->curr_msg; 504 smi_info->curr_msg = NULL; 505 if (msg->rsp[2] != 0) { 506 /* Error getting event, probably done. */ 507 msg->done(msg); 508 509 /* Take off the event flag. */ 510 smi_info->msg_flags &= ~EVENT_MSG_BUFFER_FULL; 511 handle_flags(smi_info); 512 } else { 513 spin_lock(&smi_info->count_lock); 514 smi_info->events++; 515 spin_unlock(&smi_info->count_lock); 516 517 /* Do this before we deliver the message 518 because delivering the message releases the 519 lock and something else can mess with the 520 state. */ 521 handle_flags(smi_info); 522 523 deliver_recv_msg(smi_info, msg); 524 } 525 break; 526 } 527 528 case SI_GETTING_MESSAGES: 529 { 530 smi_info->curr_msg->rsp_size 531 = smi_info->handlers->get_result( 532 smi_info->si_sm, 533 smi_info->curr_msg->rsp, 534 IPMI_MAX_MSG_LENGTH); 535 536 /* Do this here becase deliver_recv_msg() releases the 537 lock, and a new message can be put in during the 538 time the lock is released. */ 539 msg = smi_info->curr_msg; 540 smi_info->curr_msg = NULL; 541 if (msg->rsp[2] != 0) { 542 /* Error getting event, probably done. */ 543 msg->done(msg); 544 545 /* Take off the msg flag. */ 546 smi_info->msg_flags &= ~RECEIVE_MSG_AVAIL; 547 handle_flags(smi_info); 548 } else { 549 spin_lock(&smi_info->count_lock); 550 smi_info->incoming_messages++; 551 spin_unlock(&smi_info->count_lock); 552 553 /* Do this before we deliver the message 554 because delivering the message releases the 555 lock and something else can mess with the 556 state. */ 557 handle_flags(smi_info); 558 559 deliver_recv_msg(smi_info, msg); 560 } 561 break; 562 } 563 564 case SI_ENABLE_INTERRUPTS1: 565 { 566 unsigned char msg[4]; 567 568 /* We got the flags from the SMI, now handle them. */ 569 smi_info->handlers->get_result(smi_info->si_sm, msg, 4); 570 if (msg[2] != 0) { 571 printk(KERN_WARNING 572 "ipmi_si: Could not enable interrupts" 573 ", failed get, using polled mode.\n"); 574 smi_info->si_state = SI_NORMAL; 575 } else { 576 msg[0] = (IPMI_NETFN_APP_REQUEST << 2); 577 msg[1] = IPMI_SET_BMC_GLOBAL_ENABLES_CMD; 578 msg[2] = msg[3] | 1; /* enable msg queue int */ 579 smi_info->handlers->start_transaction( 580 smi_info->si_sm, msg, 3); 581 smi_info->si_state = SI_ENABLE_INTERRUPTS2; 582 } 583 break; 584 } 585 586 case SI_ENABLE_INTERRUPTS2: 587 { 588 unsigned char msg[4]; 589 590 /* We got the flags from the SMI, now handle them. */ 591 smi_info->handlers->get_result(smi_info->si_sm, msg, 4); 592 if (msg[2] != 0) { 593 printk(KERN_WARNING 594 "ipmi_si: Could not enable interrupts" 595 ", failed set, using polled mode.\n"); 596 } 597 smi_info->si_state = SI_NORMAL; 598 break; 599 } 600 } 601 } 602 603 /* Called on timeouts and events. Timeouts should pass the elapsed 604 time, interrupts should pass in zero. */ 605 static enum si_sm_result smi_event_handler(struct smi_info *smi_info, 606 int time) 607 { 608 enum si_sm_result si_sm_result; 609 610 restart: 611 /* There used to be a loop here that waited a little while 612 (around 25us) before giving up. That turned out to be 613 pointless, the minimum delays I was seeing were in the 300us 614 range, which is far too long to wait in an interrupt. So 615 we just run until the state machine tells us something 616 happened or it needs a delay. */ 617 si_sm_result = smi_info->handlers->event(smi_info->si_sm, time); 618 time = 0; 619 while (si_sm_result == SI_SM_CALL_WITHOUT_DELAY) 620 { 621 si_sm_result = smi_info->handlers->event(smi_info->si_sm, 0); 622 } 623 624 if (si_sm_result == SI_SM_TRANSACTION_COMPLETE) 625 { 626 spin_lock(&smi_info->count_lock); 627 smi_info->complete_transactions++; 628 spin_unlock(&smi_info->count_lock); 629 630 handle_transaction_done(smi_info); 631 si_sm_result = smi_info->handlers->event(smi_info->si_sm, 0); 632 } 633 else if (si_sm_result == SI_SM_HOSED) 634 { 635 spin_lock(&smi_info->count_lock); 636 smi_info->hosed_count++; 637 spin_unlock(&smi_info->count_lock); 638 639 /* Do the before return_hosed_msg, because that 640 releases the lock. */ 641 smi_info->si_state = SI_NORMAL; 642 if (smi_info->curr_msg != NULL) { 643 /* If we were handling a user message, format 644 a response to send to the upper layer to 645 tell it about the error. */ 646 return_hosed_msg(smi_info); 647 } 648 si_sm_result = smi_info->handlers->event(smi_info->si_sm, 0); 649 } 650 651 /* We prefer handling attn over new messages. */ 652 if (si_sm_result == SI_SM_ATTN) 653 { 654 unsigned char msg[2]; 655 656 spin_lock(&smi_info->count_lock); 657 smi_info->attentions++; 658 spin_unlock(&smi_info->count_lock); 659 660 /* Got a attn, send down a get message flags to see 661 what's causing it. It would be better to handle 662 this in the upper layer, but due to the way 663 interrupts work with the SMI, that's not really 664 possible. */ 665 msg[0] = (IPMI_NETFN_APP_REQUEST << 2); 666 msg[1] = IPMI_GET_MSG_FLAGS_CMD; 667 668 smi_info->handlers->start_transaction( 669 smi_info->si_sm, msg, 2); 670 smi_info->si_state = SI_GETTING_FLAGS; 671 goto restart; 672 } 673 674 /* If we are currently idle, try to start the next message. */ 675 if (si_sm_result == SI_SM_IDLE) { 676 spin_lock(&smi_info->count_lock); 677 smi_info->idles++; 678 spin_unlock(&smi_info->count_lock); 679 680 si_sm_result = start_next_msg(smi_info); 681 if (si_sm_result != SI_SM_IDLE) 682 goto restart; 683 } 684 685 if ((si_sm_result == SI_SM_IDLE) 686 && (atomic_read(&smi_info->req_events))) 687 { 688 /* We are idle and the upper layer requested that I fetch 689 events, so do so. */ 690 unsigned char msg[2]; 691 692 spin_lock(&smi_info->count_lock); 693 smi_info->flag_fetches++; 694 spin_unlock(&smi_info->count_lock); 695 696 atomic_set(&smi_info->req_events, 0); 697 msg[0] = (IPMI_NETFN_APP_REQUEST << 2); 698 msg[1] = IPMI_GET_MSG_FLAGS_CMD; 699 700 smi_info->handlers->start_transaction( 701 smi_info->si_sm, msg, 2); 702 smi_info->si_state = SI_GETTING_FLAGS; 703 goto restart; 704 } 705 706 return si_sm_result; 707 } 708 709 static void sender(void *send_info, 710 struct ipmi_smi_msg *msg, 711 int priority) 712 { 713 struct smi_info *smi_info = send_info; 714 enum si_sm_result result; 715 unsigned long flags; 716 #ifdef DEBUG_TIMING 717 struct timeval t; 718 #endif 719 720 spin_lock_irqsave(&(smi_info->msg_lock), flags); 721 #ifdef DEBUG_TIMING 722 do_gettimeofday(&t); 723 printk("**Enqueue: %d.%9.9d\n", t.tv_sec, t.tv_usec); 724 #endif 725 726 if (smi_info->run_to_completion) { 727 /* If we are running to completion, then throw it in 728 the list and run transactions until everything is 729 clear. Priority doesn't matter here. */ 730 list_add_tail(&(msg->link), &(smi_info->xmit_msgs)); 731 732 /* We have to release the msg lock and claim the smi 733 lock in this case, because of race conditions. */ 734 spin_unlock_irqrestore(&(smi_info->msg_lock), flags); 735 736 spin_lock_irqsave(&(smi_info->si_lock), flags); 737 result = smi_event_handler(smi_info, 0); 738 while (result != SI_SM_IDLE) { 739 udelay(SI_SHORT_TIMEOUT_USEC); 740 result = smi_event_handler(smi_info, 741 SI_SHORT_TIMEOUT_USEC); 742 } 743 spin_unlock_irqrestore(&(smi_info->si_lock), flags); 744 return; 745 } else { 746 if (priority > 0) { 747 list_add_tail(&(msg->link), &(smi_info->hp_xmit_msgs)); 748 } else { 749 list_add_tail(&(msg->link), &(smi_info->xmit_msgs)); 750 } 751 } 752 spin_unlock_irqrestore(&(smi_info->msg_lock), flags); 753 754 spin_lock_irqsave(&(smi_info->si_lock), flags); 755 if ((smi_info->si_state == SI_NORMAL) 756 && (smi_info->curr_msg == NULL)) 757 { 758 start_next_msg(smi_info); 759 si_restart_short_timer(smi_info); 760 } 761 spin_unlock_irqrestore(&(smi_info->si_lock), flags); 762 } 763 764 static void set_run_to_completion(void *send_info, int i_run_to_completion) 765 { 766 struct smi_info *smi_info = send_info; 767 enum si_sm_result result; 768 unsigned long flags; 769 770 spin_lock_irqsave(&(smi_info->si_lock), flags); 771 772 smi_info->run_to_completion = i_run_to_completion; 773 if (i_run_to_completion) { 774 result = smi_event_handler(smi_info, 0); 775 while (result != SI_SM_IDLE) { 776 udelay(SI_SHORT_TIMEOUT_USEC); 777 result = smi_event_handler(smi_info, 778 SI_SHORT_TIMEOUT_USEC); 779 } 780 } 781 782 spin_unlock_irqrestore(&(smi_info->si_lock), flags); 783 } 784 785 static int ipmi_thread(void *data) 786 { 787 struct smi_info *smi_info = data; 788 unsigned long flags; 789 enum si_sm_result smi_result; 790 791 set_user_nice(current, 19); 792 while (!kthread_should_stop()) { 793 spin_lock_irqsave(&(smi_info->si_lock), flags); 794 smi_result=smi_event_handler(smi_info, 0); 795 spin_unlock_irqrestore(&(smi_info->si_lock), flags); 796 if (smi_result == SI_SM_CALL_WITHOUT_DELAY) { 797 /* do nothing */ 798 } 799 else if (smi_result == SI_SM_CALL_WITH_DELAY) 800 udelay(1); 801 else 802 schedule_timeout_interruptible(1); 803 } 804 return 0; 805 } 806 807 808 static void poll(void *send_info) 809 { 810 struct smi_info *smi_info = send_info; 811 812 smi_event_handler(smi_info, 0); 813 } 814 815 static void request_events(void *send_info) 816 { 817 struct smi_info *smi_info = send_info; 818 819 atomic_set(&smi_info->req_events, 1); 820 } 821 822 static int initialized = 0; 823 824 /* Must be called with interrupts off and with the si_lock held. */ 825 static void si_restart_short_timer(struct smi_info *smi_info) 826 { 827 #if defined(CONFIG_HIGH_RES_TIMERS) 828 unsigned long flags; 829 unsigned long jiffies_now; 830 unsigned long seq; 831 832 if (del_timer(&(smi_info->si_timer))) { 833 /* If we don't delete the timer, then it will go off 834 immediately, anyway. So we only process if we 835 actually delete the timer. */ 836 837 do { 838 seq = read_seqbegin_irqsave(&xtime_lock, flags); 839 jiffies_now = jiffies; 840 smi_info->si_timer.expires = jiffies_now; 841 smi_info->si_timer.arch_cycle_expires 842 = get_arch_cycles(jiffies_now); 843 } while (read_seqretry_irqrestore(&xtime_lock, seq, flags)); 844 845 add_usec_to_timer(&smi_info->si_timer, SI_SHORT_TIMEOUT_USEC); 846 847 add_timer(&(smi_info->si_timer)); 848 spin_lock_irqsave(&smi_info->count_lock, flags); 849 smi_info->timeout_restarts++; 850 spin_unlock_irqrestore(&smi_info->count_lock, flags); 851 } 852 #endif 853 } 854 855 static void smi_timeout(unsigned long data) 856 { 857 struct smi_info *smi_info = (struct smi_info *) data; 858 enum si_sm_result smi_result; 859 unsigned long flags; 860 unsigned long jiffies_now; 861 long time_diff; 862 #ifdef DEBUG_TIMING 863 struct timeval t; 864 #endif 865 866 if (atomic_read(&smi_info->stop_operation)) 867 return; 868 869 spin_lock_irqsave(&(smi_info->si_lock), flags); 870 #ifdef DEBUG_TIMING 871 do_gettimeofday(&t); 872 printk("**Timer: %d.%9.9d\n", t.tv_sec, t.tv_usec); 873 #endif 874 jiffies_now = jiffies; 875 time_diff = (((long)jiffies_now - (long)smi_info->last_timeout_jiffies) 876 * SI_USEC_PER_JIFFY); 877 smi_result = smi_event_handler(smi_info, time_diff); 878 879 spin_unlock_irqrestore(&(smi_info->si_lock), flags); 880 881 smi_info->last_timeout_jiffies = jiffies_now; 882 883 if ((smi_info->irq) && (! smi_info->interrupt_disabled)) { 884 /* Running with interrupts, only do long timeouts. */ 885 smi_info->si_timer.expires = jiffies + SI_TIMEOUT_JIFFIES; 886 spin_lock_irqsave(&smi_info->count_lock, flags); 887 smi_info->long_timeouts++; 888 spin_unlock_irqrestore(&smi_info->count_lock, flags); 889 goto do_add_timer; 890 } 891 892 /* If the state machine asks for a short delay, then shorten 893 the timer timeout. */ 894 if (smi_result == SI_SM_CALL_WITH_DELAY) { 895 #if defined(CONFIG_HIGH_RES_TIMERS) 896 unsigned long seq; 897 #endif 898 spin_lock_irqsave(&smi_info->count_lock, flags); 899 smi_info->short_timeouts++; 900 spin_unlock_irqrestore(&smi_info->count_lock, flags); 901 #if defined(CONFIG_HIGH_RES_TIMERS) 902 do { 903 seq = read_seqbegin_irqsave(&xtime_lock, flags); 904 smi_info->si_timer.expires = jiffies; 905 smi_info->si_timer.arch_cycle_expires 906 = get_arch_cycles(smi_info->si_timer.expires); 907 } while (read_seqretry_irqrestore(&xtime_lock, seq, flags)); 908 add_usec_to_timer(&smi_info->si_timer, SI_SHORT_TIMEOUT_USEC); 909 #else 910 smi_info->si_timer.expires = jiffies + 1; 911 #endif 912 } else { 913 spin_lock_irqsave(&smi_info->count_lock, flags); 914 smi_info->long_timeouts++; 915 spin_unlock_irqrestore(&smi_info->count_lock, flags); 916 smi_info->si_timer.expires = jiffies + SI_TIMEOUT_JIFFIES; 917 #if defined(CONFIG_HIGH_RES_TIMERS) 918 smi_info->si_timer.arch_cycle_expires = 0; 919 #endif 920 } 921 922 do_add_timer: 923 add_timer(&(smi_info->si_timer)); 924 } 925 926 static irqreturn_t si_irq_handler(int irq, void *data, struct pt_regs *regs) 927 { 928 struct smi_info *smi_info = data; 929 unsigned long flags; 930 #ifdef DEBUG_TIMING 931 struct timeval t; 932 #endif 933 934 spin_lock_irqsave(&(smi_info->si_lock), flags); 935 936 spin_lock(&smi_info->count_lock); 937 smi_info->interrupts++; 938 spin_unlock(&smi_info->count_lock); 939 940 if (atomic_read(&smi_info->stop_operation)) 941 goto out; 942 943 #ifdef DEBUG_TIMING 944 do_gettimeofday(&t); 945 printk("**Interrupt: %d.%9.9d\n", t.tv_sec, t.tv_usec); 946 #endif 947 smi_event_handler(smi_info, 0); 948 out: 949 spin_unlock_irqrestore(&(smi_info->si_lock), flags); 950 return IRQ_HANDLED; 951 } 952 953 static irqreturn_t si_bt_irq_handler(int irq, void *data, struct pt_regs *regs) 954 { 955 struct smi_info *smi_info = data; 956 /* We need to clear the IRQ flag for the BT interface. */ 957 smi_info->io.outputb(&smi_info->io, IPMI_BT_INTMASK_REG, 958 IPMI_BT_INTMASK_CLEAR_IRQ_BIT 959 | IPMI_BT_INTMASK_ENABLE_IRQ_BIT); 960 return si_irq_handler(irq, data, regs); 961 } 962 963 964 static struct ipmi_smi_handlers handlers = 965 { 966 .owner = THIS_MODULE, 967 .sender = sender, 968 .request_events = request_events, 969 .set_run_to_completion = set_run_to_completion, 970 .poll = poll, 971 }; 972 973 /* There can be 4 IO ports passed in (with or without IRQs), 4 addresses, 974 a default IO port, and 1 ACPI/SPMI address. That sets SI_MAX_DRIVERS */ 975 976 #define SI_MAX_PARMS 4 977 #define SI_MAX_DRIVERS ((SI_MAX_PARMS * 2) + 2) 978 static struct smi_info *smi_infos[SI_MAX_DRIVERS] = 979 { NULL, NULL, NULL, NULL }; 980 981 #define DEVICE_NAME "ipmi_si" 982 983 #define DEFAULT_KCS_IO_PORT 0xca2 984 #define DEFAULT_SMIC_IO_PORT 0xca9 985 #define DEFAULT_BT_IO_PORT 0xe4 986 #define DEFAULT_REGSPACING 1 987 988 static int si_trydefaults = 1; 989 static char *si_type[SI_MAX_PARMS]; 990 #define MAX_SI_TYPE_STR 30 991 static char si_type_str[MAX_SI_TYPE_STR]; 992 static unsigned long addrs[SI_MAX_PARMS]; 993 static int num_addrs; 994 static unsigned int ports[SI_MAX_PARMS]; 995 static int num_ports; 996 static int irqs[SI_MAX_PARMS]; 997 static int num_irqs; 998 static int regspacings[SI_MAX_PARMS]; 999 static int num_regspacings = 0; 1000 static int regsizes[SI_MAX_PARMS]; 1001 static int num_regsizes = 0; 1002 static int regshifts[SI_MAX_PARMS]; 1003 static int num_regshifts = 0; 1004 static int slave_addrs[SI_MAX_PARMS]; 1005 static int num_slave_addrs = 0; 1006 1007 1008 module_param_named(trydefaults, si_trydefaults, bool, 0); 1009 MODULE_PARM_DESC(trydefaults, "Setting this to 'false' will disable the" 1010 " default scan of the KCS and SMIC interface at the standard" 1011 " address"); 1012 module_param_string(type, si_type_str, MAX_SI_TYPE_STR, 0); 1013 MODULE_PARM_DESC(type, "Defines the type of each interface, each" 1014 " interface separated by commas. The types are 'kcs'," 1015 " 'smic', and 'bt'. For example si_type=kcs,bt will set" 1016 " the first interface to kcs and the second to bt"); 1017 module_param_array(addrs, long, &num_addrs, 0); 1018 MODULE_PARM_DESC(addrs, "Sets the memory address of each interface, the" 1019 " addresses separated by commas. Only use if an interface" 1020 " is in memory. Otherwise, set it to zero or leave" 1021 " it blank."); 1022 module_param_array(ports, int, &num_ports, 0); 1023 MODULE_PARM_DESC(ports, "Sets the port address of each interface, the" 1024 " addresses separated by commas. Only use if an interface" 1025 " is a port. Otherwise, set it to zero or leave" 1026 " it blank."); 1027 module_param_array(irqs, int, &num_irqs, 0); 1028 MODULE_PARM_DESC(irqs, "Sets the interrupt of each interface, the" 1029 " addresses separated by commas. Only use if an interface" 1030 " has an interrupt. Otherwise, set it to zero or leave" 1031 " it blank."); 1032 module_param_array(regspacings, int, &num_regspacings, 0); 1033 MODULE_PARM_DESC(regspacings, "The number of bytes between the start address" 1034 " and each successive register used by the interface. For" 1035 " instance, if the start address is 0xca2 and the spacing" 1036 " is 2, then the second address is at 0xca4. Defaults" 1037 " to 1."); 1038 module_param_array(regsizes, int, &num_regsizes, 0); 1039 MODULE_PARM_DESC(regsizes, "The size of the specific IPMI register in bytes." 1040 " This should generally be 1, 2, 4, or 8 for an 8-bit," 1041 " 16-bit, 32-bit, or 64-bit register. Use this if you" 1042 " the 8-bit IPMI register has to be read from a larger" 1043 " register."); 1044 module_param_array(regshifts, int, &num_regshifts, 0); 1045 MODULE_PARM_DESC(regshifts, "The amount to shift the data read from the." 1046 " IPMI register, in bits. For instance, if the data" 1047 " is read from a 32-bit word and the IPMI data is in" 1048 " bit 8-15, then the shift would be 8"); 1049 module_param_array(slave_addrs, int, &num_slave_addrs, 0); 1050 MODULE_PARM_DESC(slave_addrs, "Set the default IPMB slave address for" 1051 " the controller. Normally this is 0x20, but can be" 1052 " overridden by this parm. This is an array indexed" 1053 " by interface number."); 1054 1055 1056 #define IPMI_MEM_ADDR_SPACE 1 1057 #define IPMI_IO_ADDR_SPACE 2 1058 1059 #if defined(CONFIG_ACPI) || defined(CONFIG_X86) || defined(CONFIG_PCI) 1060 static int is_new_interface(int intf, u8 addr_space, unsigned long base_addr) 1061 { 1062 int i; 1063 1064 for (i = 0; i < SI_MAX_PARMS; ++i) { 1065 /* Don't check our address. */ 1066 if (i == intf) 1067 continue; 1068 if (si_type[i] != NULL) { 1069 if ((addr_space == IPMI_MEM_ADDR_SPACE && 1070 base_addr == addrs[i]) || 1071 (addr_space == IPMI_IO_ADDR_SPACE && 1072 base_addr == ports[i])) 1073 return 0; 1074 } 1075 else 1076 break; 1077 } 1078 1079 return 1; 1080 } 1081 #endif 1082 1083 static int std_irq_setup(struct smi_info *info) 1084 { 1085 int rv; 1086 1087 if (! info->irq) 1088 return 0; 1089 1090 if (info->si_type == SI_BT) { 1091 rv = request_irq(info->irq, 1092 si_bt_irq_handler, 1093 SA_INTERRUPT, 1094 DEVICE_NAME, 1095 info); 1096 if (! rv) 1097 /* Enable the interrupt in the BT interface. */ 1098 info->io.outputb(&info->io, IPMI_BT_INTMASK_REG, 1099 IPMI_BT_INTMASK_ENABLE_IRQ_BIT); 1100 } else 1101 rv = request_irq(info->irq, 1102 si_irq_handler, 1103 SA_INTERRUPT, 1104 DEVICE_NAME, 1105 info); 1106 if (rv) { 1107 printk(KERN_WARNING 1108 "ipmi_si: %s unable to claim interrupt %d," 1109 " running polled\n", 1110 DEVICE_NAME, info->irq); 1111 info->irq = 0; 1112 } else { 1113 printk(" Using irq %d\n", info->irq); 1114 } 1115 1116 return rv; 1117 } 1118 1119 static void std_irq_cleanup(struct smi_info *info) 1120 { 1121 if (! info->irq) 1122 return; 1123 1124 if (info->si_type == SI_BT) 1125 /* Disable the interrupt in the BT interface. */ 1126 info->io.outputb(&info->io, IPMI_BT_INTMASK_REG, 0); 1127 free_irq(info->irq, info); 1128 } 1129 1130 static unsigned char port_inb(struct si_sm_io *io, unsigned int offset) 1131 { 1132 unsigned int *addr = io->info; 1133 1134 return inb((*addr)+(offset*io->regspacing)); 1135 } 1136 1137 static void port_outb(struct si_sm_io *io, unsigned int offset, 1138 unsigned char b) 1139 { 1140 unsigned int *addr = io->info; 1141 1142 outb(b, (*addr)+(offset * io->regspacing)); 1143 } 1144 1145 static unsigned char port_inw(struct si_sm_io *io, unsigned int offset) 1146 { 1147 unsigned int *addr = io->info; 1148 1149 return (inw((*addr)+(offset * io->regspacing)) >> io->regshift) & 0xff; 1150 } 1151 1152 static void port_outw(struct si_sm_io *io, unsigned int offset, 1153 unsigned char b) 1154 { 1155 unsigned int *addr = io->info; 1156 1157 outw(b << io->regshift, (*addr)+(offset * io->regspacing)); 1158 } 1159 1160 static unsigned char port_inl(struct si_sm_io *io, unsigned int offset) 1161 { 1162 unsigned int *addr = io->info; 1163 1164 return (inl((*addr)+(offset * io->regspacing)) >> io->regshift) & 0xff; 1165 } 1166 1167 static void port_outl(struct si_sm_io *io, unsigned int offset, 1168 unsigned char b) 1169 { 1170 unsigned int *addr = io->info; 1171 1172 outl(b << io->regshift, (*addr)+(offset * io->regspacing)); 1173 } 1174 1175 static void port_cleanup(struct smi_info *info) 1176 { 1177 unsigned int *addr = info->io.info; 1178 int mapsize; 1179 1180 if (addr && (*addr)) { 1181 mapsize = ((info->io_size * info->io.regspacing) 1182 - (info->io.regspacing - info->io.regsize)); 1183 1184 release_region (*addr, mapsize); 1185 } 1186 kfree(info); 1187 } 1188 1189 static int port_setup(struct smi_info *info) 1190 { 1191 unsigned int *addr = info->io.info; 1192 int mapsize; 1193 1194 if (! addr || (! *addr)) 1195 return -ENODEV; 1196 1197 info->io_cleanup = port_cleanup; 1198 1199 /* Figure out the actual inb/inw/inl/etc routine to use based 1200 upon the register size. */ 1201 switch (info->io.regsize) { 1202 case 1: 1203 info->io.inputb = port_inb; 1204 info->io.outputb = port_outb; 1205 break; 1206 case 2: 1207 info->io.inputb = port_inw; 1208 info->io.outputb = port_outw; 1209 break; 1210 case 4: 1211 info->io.inputb = port_inl; 1212 info->io.outputb = port_outl; 1213 break; 1214 default: 1215 printk("ipmi_si: Invalid register size: %d\n", 1216 info->io.regsize); 1217 return -EINVAL; 1218 } 1219 1220 /* Calculate the total amount of memory to claim. This is an 1221 * unusual looking calculation, but it avoids claiming any 1222 * more memory than it has to. It will claim everything 1223 * between the first address to the end of the last full 1224 * register. */ 1225 mapsize = ((info->io_size * info->io.regspacing) 1226 - (info->io.regspacing - info->io.regsize)); 1227 1228 if (request_region(*addr, mapsize, DEVICE_NAME) == NULL) 1229 return -EIO; 1230 return 0; 1231 } 1232 1233 static int try_init_port(int intf_num, struct smi_info **new_info) 1234 { 1235 struct smi_info *info; 1236 1237 if (! ports[intf_num]) 1238 return -ENODEV; 1239 1240 if (! is_new_interface(intf_num, IPMI_IO_ADDR_SPACE, 1241 ports[intf_num])) 1242 return -ENODEV; 1243 1244 info = kmalloc(sizeof(*info), GFP_KERNEL); 1245 if (! info) { 1246 printk(KERN_ERR "ipmi_si: Could not allocate SI data (1)\n"); 1247 return -ENOMEM; 1248 } 1249 memset(info, 0, sizeof(*info)); 1250 1251 info->io_setup = port_setup; 1252 info->io.info = &(ports[intf_num]); 1253 info->io.addr = NULL; 1254 info->io.regspacing = regspacings[intf_num]; 1255 if (! info->io.regspacing) 1256 info->io.regspacing = DEFAULT_REGSPACING; 1257 info->io.regsize = regsizes[intf_num]; 1258 if (! info->io.regsize) 1259 info->io.regsize = DEFAULT_REGSPACING; 1260 info->io.regshift = regshifts[intf_num]; 1261 info->irq = 0; 1262 info->irq_setup = NULL; 1263 *new_info = info; 1264 1265 if (si_type[intf_num] == NULL) 1266 si_type[intf_num] = "kcs"; 1267 1268 printk("ipmi_si: Trying \"%s\" at I/O port 0x%x\n", 1269 si_type[intf_num], ports[intf_num]); 1270 return 0; 1271 } 1272 1273 static unsigned char mem_inb(struct si_sm_io *io, unsigned int offset) 1274 { 1275 return readb((io->addr)+(offset * io->regspacing)); 1276 } 1277 1278 static void mem_outb(struct si_sm_io *io, unsigned int offset, 1279 unsigned char b) 1280 { 1281 writeb(b, (io->addr)+(offset * io->regspacing)); 1282 } 1283 1284 static unsigned char mem_inw(struct si_sm_io *io, unsigned int offset) 1285 { 1286 return (readw((io->addr)+(offset * io->regspacing)) >> io->regshift) 1287 && 0xff; 1288 } 1289 1290 static void mem_outw(struct si_sm_io *io, unsigned int offset, 1291 unsigned char b) 1292 { 1293 writeb(b << io->regshift, (io->addr)+(offset * io->regspacing)); 1294 } 1295 1296 static unsigned char mem_inl(struct si_sm_io *io, unsigned int offset) 1297 { 1298 return (readl((io->addr)+(offset * io->regspacing)) >> io->regshift) 1299 && 0xff; 1300 } 1301 1302 static void mem_outl(struct si_sm_io *io, unsigned int offset, 1303 unsigned char b) 1304 { 1305 writel(b << io->regshift, (io->addr)+(offset * io->regspacing)); 1306 } 1307 1308 #ifdef readq 1309 static unsigned char mem_inq(struct si_sm_io *io, unsigned int offset) 1310 { 1311 return (readq((io->addr)+(offset * io->regspacing)) >> io->regshift) 1312 && 0xff; 1313 } 1314 1315 static void mem_outq(struct si_sm_io *io, unsigned int offset, 1316 unsigned char b) 1317 { 1318 writeq(b << io->regshift, (io->addr)+(offset * io->regspacing)); 1319 } 1320 #endif 1321 1322 static void mem_cleanup(struct smi_info *info) 1323 { 1324 unsigned long *addr = info->io.info; 1325 int mapsize; 1326 1327 if (info->io.addr) { 1328 iounmap(info->io.addr); 1329 1330 mapsize = ((info->io_size * info->io.regspacing) 1331 - (info->io.regspacing - info->io.regsize)); 1332 1333 release_mem_region(*addr, mapsize); 1334 } 1335 kfree(info); 1336 } 1337 1338 static int mem_setup(struct smi_info *info) 1339 { 1340 unsigned long *addr = info->io.info; 1341 int mapsize; 1342 1343 if (! addr || (! *addr)) 1344 return -ENODEV; 1345 1346 info->io_cleanup = mem_cleanup; 1347 1348 /* Figure out the actual readb/readw/readl/etc routine to use based 1349 upon the register size. */ 1350 switch (info->io.regsize) { 1351 case 1: 1352 info->io.inputb = mem_inb; 1353 info->io.outputb = mem_outb; 1354 break; 1355 case 2: 1356 info->io.inputb = mem_inw; 1357 info->io.outputb = mem_outw; 1358 break; 1359 case 4: 1360 info->io.inputb = mem_inl; 1361 info->io.outputb = mem_outl; 1362 break; 1363 #ifdef readq 1364 case 8: 1365 info->io.inputb = mem_inq; 1366 info->io.outputb = mem_outq; 1367 break; 1368 #endif 1369 default: 1370 printk("ipmi_si: Invalid register size: %d\n", 1371 info->io.regsize); 1372 return -EINVAL; 1373 } 1374 1375 /* Calculate the total amount of memory to claim. This is an 1376 * unusual looking calculation, but it avoids claiming any 1377 * more memory than it has to. It will claim everything 1378 * between the first address to the end of the last full 1379 * register. */ 1380 mapsize = ((info->io_size * info->io.regspacing) 1381 - (info->io.regspacing - info->io.regsize)); 1382 1383 if (request_mem_region(*addr, mapsize, DEVICE_NAME) == NULL) 1384 return -EIO; 1385 1386 info->io.addr = ioremap(*addr, mapsize); 1387 if (info->io.addr == NULL) { 1388 release_mem_region(*addr, mapsize); 1389 return -EIO; 1390 } 1391 return 0; 1392 } 1393 1394 static int try_init_mem(int intf_num, struct smi_info **new_info) 1395 { 1396 struct smi_info *info; 1397 1398 if (! addrs[intf_num]) 1399 return -ENODEV; 1400 1401 if (! is_new_interface(intf_num, IPMI_MEM_ADDR_SPACE, 1402 addrs[intf_num])) 1403 return -ENODEV; 1404 1405 info = kmalloc(sizeof(*info), GFP_KERNEL); 1406 if (! info) { 1407 printk(KERN_ERR "ipmi_si: Could not allocate SI data (2)\n"); 1408 return -ENOMEM; 1409 } 1410 memset(info, 0, sizeof(*info)); 1411 1412 info->io_setup = mem_setup; 1413 info->io.info = &addrs[intf_num]; 1414 info->io.addr = NULL; 1415 info->io.regspacing = regspacings[intf_num]; 1416 if (! info->io.regspacing) 1417 info->io.regspacing = DEFAULT_REGSPACING; 1418 info->io.regsize = regsizes[intf_num]; 1419 if (! info->io.regsize) 1420 info->io.regsize = DEFAULT_REGSPACING; 1421 info->io.regshift = regshifts[intf_num]; 1422 info->irq = 0; 1423 info->irq_setup = NULL; 1424 *new_info = info; 1425 1426 if (si_type[intf_num] == NULL) 1427 si_type[intf_num] = "kcs"; 1428 1429 printk("ipmi_si: Trying \"%s\" at memory address 0x%lx\n", 1430 si_type[intf_num], addrs[intf_num]); 1431 return 0; 1432 } 1433 1434 1435 #ifdef CONFIG_ACPI 1436 1437 #include <linux/acpi.h> 1438 1439 /* Once we get an ACPI failure, we don't try any more, because we go 1440 through the tables sequentially. Once we don't find a table, there 1441 are no more. */ 1442 static int acpi_failure = 0; 1443 1444 /* For GPE-type interrupts. */ 1445 static u32 ipmi_acpi_gpe(void *context) 1446 { 1447 struct smi_info *smi_info = context; 1448 unsigned long flags; 1449 #ifdef DEBUG_TIMING 1450 struct timeval t; 1451 #endif 1452 1453 spin_lock_irqsave(&(smi_info->si_lock), flags); 1454 1455 spin_lock(&smi_info->count_lock); 1456 smi_info->interrupts++; 1457 spin_unlock(&smi_info->count_lock); 1458 1459 if (atomic_read(&smi_info->stop_operation)) 1460 goto out; 1461 1462 #ifdef DEBUG_TIMING 1463 do_gettimeofday(&t); 1464 printk("**ACPI_GPE: %d.%9.9d\n", t.tv_sec, t.tv_usec); 1465 #endif 1466 smi_event_handler(smi_info, 0); 1467 out: 1468 spin_unlock_irqrestore(&(smi_info->si_lock), flags); 1469 1470 return ACPI_INTERRUPT_HANDLED; 1471 } 1472 1473 static int acpi_gpe_irq_setup(struct smi_info *info) 1474 { 1475 acpi_status status; 1476 1477 if (! info->irq) 1478 return 0; 1479 1480 /* FIXME - is level triggered right? */ 1481 status = acpi_install_gpe_handler(NULL, 1482 info->irq, 1483 ACPI_GPE_LEVEL_TRIGGERED, 1484 &ipmi_acpi_gpe, 1485 info); 1486 if (status != AE_OK) { 1487 printk(KERN_WARNING 1488 "ipmi_si: %s unable to claim ACPI GPE %d," 1489 " running polled\n", 1490 DEVICE_NAME, info->irq); 1491 info->irq = 0; 1492 return -EINVAL; 1493 } else { 1494 printk(" Using ACPI GPE %d\n", info->irq); 1495 return 0; 1496 } 1497 } 1498 1499 static void acpi_gpe_irq_cleanup(struct smi_info *info) 1500 { 1501 if (! info->irq) 1502 return; 1503 1504 acpi_remove_gpe_handler(NULL, info->irq, &ipmi_acpi_gpe); 1505 } 1506 1507 /* 1508 * Defined at 1509 * http://h21007.www2.hp.com/dspp/files/unprotected/devresource/Docs/TechPapers/IA64/hpspmi.pdf 1510 */ 1511 struct SPMITable { 1512 s8 Signature[4]; 1513 u32 Length; 1514 u8 Revision; 1515 u8 Checksum; 1516 s8 OEMID[6]; 1517 s8 OEMTableID[8]; 1518 s8 OEMRevision[4]; 1519 s8 CreatorID[4]; 1520 s8 CreatorRevision[4]; 1521 u8 InterfaceType; 1522 u8 IPMIlegacy; 1523 s16 SpecificationRevision; 1524 1525 /* 1526 * Bit 0 - SCI interrupt supported 1527 * Bit 1 - I/O APIC/SAPIC 1528 */ 1529 u8 InterruptType; 1530 1531 /* If bit 0 of InterruptType is set, then this is the SCI 1532 interrupt in the GPEx_STS register. */ 1533 u8 GPE; 1534 1535 s16 Reserved; 1536 1537 /* If bit 1 of InterruptType is set, then this is the I/O 1538 APIC/SAPIC interrupt. */ 1539 u32 GlobalSystemInterrupt; 1540 1541 /* The actual register address. */ 1542 struct acpi_generic_address addr; 1543 1544 u8 UID[4]; 1545 1546 s8 spmi_id[1]; /* A '\0' terminated array starts here. */ 1547 }; 1548 1549 static int try_init_acpi(int intf_num, struct smi_info **new_info) 1550 { 1551 struct smi_info *info; 1552 acpi_status status; 1553 struct SPMITable *spmi; 1554 char *io_type; 1555 u8 addr_space; 1556 1557 if (acpi_disabled) 1558 return -ENODEV; 1559 1560 if (acpi_failure) 1561 return -ENODEV; 1562 1563 status = acpi_get_firmware_table("SPMI", intf_num+1, 1564 ACPI_LOGICAL_ADDRESSING, 1565 (struct acpi_table_header **) &spmi); 1566 if (status != AE_OK) { 1567 acpi_failure = 1; 1568 return -ENODEV; 1569 } 1570 1571 if (spmi->IPMIlegacy != 1) { 1572 printk(KERN_INFO "IPMI: Bad SPMI legacy %d\n", spmi->IPMIlegacy); 1573 return -ENODEV; 1574 } 1575 1576 if (spmi->addr.address_space_id == ACPI_ADR_SPACE_SYSTEM_MEMORY) 1577 addr_space = IPMI_MEM_ADDR_SPACE; 1578 else 1579 addr_space = IPMI_IO_ADDR_SPACE; 1580 if (! is_new_interface(-1, addr_space, spmi->addr.address)) 1581 return -ENODEV; 1582 1583 if (! spmi->addr.register_bit_width) { 1584 acpi_failure = 1; 1585 return -ENODEV; 1586 } 1587 1588 /* Figure out the interface type. */ 1589 switch (spmi->InterfaceType) 1590 { 1591 case 1: /* KCS */ 1592 si_type[intf_num] = "kcs"; 1593 break; 1594 1595 case 2: /* SMIC */ 1596 si_type[intf_num] = "smic"; 1597 break; 1598 1599 case 3: /* BT */ 1600 si_type[intf_num] = "bt"; 1601 break; 1602 1603 default: 1604 printk(KERN_INFO "ipmi_si: Unknown ACPI/SPMI SI type %d\n", 1605 spmi->InterfaceType); 1606 return -EIO; 1607 } 1608 1609 info = kmalloc(sizeof(*info), GFP_KERNEL); 1610 if (! info) { 1611 printk(KERN_ERR "ipmi_si: Could not allocate SI data (3)\n"); 1612 return -ENOMEM; 1613 } 1614 memset(info, 0, sizeof(*info)); 1615 1616 if (spmi->InterruptType & 1) { 1617 /* We've got a GPE interrupt. */ 1618 info->irq = spmi->GPE; 1619 info->irq_setup = acpi_gpe_irq_setup; 1620 info->irq_cleanup = acpi_gpe_irq_cleanup; 1621 } else if (spmi->InterruptType & 2) { 1622 /* We've got an APIC/SAPIC interrupt. */ 1623 info->irq = spmi->GlobalSystemInterrupt; 1624 info->irq_setup = std_irq_setup; 1625 info->irq_cleanup = std_irq_cleanup; 1626 } else { 1627 /* Use the default interrupt setting. */ 1628 info->irq = 0; 1629 info->irq_setup = NULL; 1630 } 1631 1632 if (spmi->addr.register_bit_width) { 1633 /* A (hopefully) properly formed register bit width. */ 1634 regspacings[intf_num] = spmi->addr.register_bit_width / 8; 1635 info->io.regspacing = spmi->addr.register_bit_width / 8; 1636 } else { 1637 /* Some broken systems get this wrong and set the value 1638 * to zero. Assume it is the default spacing. If that 1639 * is wrong, too bad, the vendor should fix the tables. */ 1640 regspacings[intf_num] = DEFAULT_REGSPACING; 1641 info->io.regspacing = DEFAULT_REGSPACING; 1642 } 1643 regsizes[intf_num] = regspacings[intf_num]; 1644 info->io.regsize = regsizes[intf_num]; 1645 regshifts[intf_num] = spmi->addr.register_bit_offset; 1646 info->io.regshift = regshifts[intf_num]; 1647 1648 if (spmi->addr.address_space_id == ACPI_ADR_SPACE_SYSTEM_MEMORY) { 1649 io_type = "memory"; 1650 info->io_setup = mem_setup; 1651 addrs[intf_num] = spmi->addr.address; 1652 info->io.info = &(addrs[intf_num]); 1653 } else if (spmi->addr.address_space_id == ACPI_ADR_SPACE_SYSTEM_IO) { 1654 io_type = "I/O"; 1655 info->io_setup = port_setup; 1656 ports[intf_num] = spmi->addr.address; 1657 info->io.info = &(ports[intf_num]); 1658 } else { 1659 kfree(info); 1660 printk("ipmi_si: Unknown ACPI I/O Address type\n"); 1661 return -EIO; 1662 } 1663 1664 *new_info = info; 1665 1666 printk("ipmi_si: ACPI/SPMI specifies \"%s\" %s SI @ 0x%lx\n", 1667 si_type[intf_num], io_type, (unsigned long) spmi->addr.address); 1668 return 0; 1669 } 1670 #endif 1671 1672 #ifdef CONFIG_X86 1673 typedef struct dmi_ipmi_data 1674 { 1675 u8 type; 1676 u8 addr_space; 1677 unsigned long base_addr; 1678 u8 irq; 1679 u8 offset; 1680 u8 slave_addr; 1681 } dmi_ipmi_data_t; 1682 1683 static dmi_ipmi_data_t dmi_data[SI_MAX_DRIVERS]; 1684 static int dmi_data_entries; 1685 1686 static int __init decode_dmi(struct dmi_header *dm, int intf_num) 1687 { 1688 u8 *data = (u8 *)dm; 1689 unsigned long base_addr; 1690 u8 reg_spacing; 1691 u8 len = dm->length; 1692 dmi_ipmi_data_t *ipmi_data = dmi_data+intf_num; 1693 1694 ipmi_data->type = data[4]; 1695 1696 memcpy(&base_addr, data+8, sizeof(unsigned long)); 1697 if (len >= 0x11) { 1698 if (base_addr & 1) { 1699 /* I/O */ 1700 base_addr &= 0xFFFE; 1701 ipmi_data->addr_space = IPMI_IO_ADDR_SPACE; 1702 } 1703 else { 1704 /* Memory */ 1705 ipmi_data->addr_space = IPMI_MEM_ADDR_SPACE; 1706 } 1707 /* If bit 4 of byte 0x10 is set, then the lsb for the address 1708 is odd. */ 1709 ipmi_data->base_addr = base_addr | ((data[0x10] & 0x10) >> 4); 1710 1711 ipmi_data->irq = data[0x11]; 1712 1713 /* The top two bits of byte 0x10 hold the register spacing. */ 1714 reg_spacing = (data[0x10] & 0xC0) >> 6; 1715 switch(reg_spacing){ 1716 case 0x00: /* Byte boundaries */ 1717 ipmi_data->offset = 1; 1718 break; 1719 case 0x01: /* 32-bit boundaries */ 1720 ipmi_data->offset = 4; 1721 break; 1722 case 0x02: /* 16-byte boundaries */ 1723 ipmi_data->offset = 16; 1724 break; 1725 default: 1726 /* Some other interface, just ignore it. */ 1727 return -EIO; 1728 } 1729 } else { 1730 /* Old DMI spec. */ 1731 /* Note that technically, the lower bit of the base 1732 * address should be 1 if the address is I/O and 0 if 1733 * the address is in memory. So many systems get that 1734 * wrong (and all that I have seen are I/O) so we just 1735 * ignore that bit and assume I/O. Systems that use 1736 * memory should use the newer spec, anyway. */ 1737 ipmi_data->base_addr = base_addr & 0xfffe; 1738 ipmi_data->addr_space = IPMI_IO_ADDR_SPACE; 1739 ipmi_data->offset = 1; 1740 } 1741 1742 ipmi_data->slave_addr = data[6]; 1743 1744 if (is_new_interface(-1, ipmi_data->addr_space,ipmi_data->base_addr)) { 1745 dmi_data_entries++; 1746 return 0; 1747 } 1748 1749 memset(ipmi_data, 0, sizeof(dmi_ipmi_data_t)); 1750 1751 return -1; 1752 } 1753 1754 static void __init dmi_find_bmc(void) 1755 { 1756 struct dmi_device *dev = NULL; 1757 int intf_num = 0; 1758 1759 while ((dev = dmi_find_device(DMI_DEV_TYPE_IPMI, NULL, dev))) { 1760 if (intf_num >= SI_MAX_DRIVERS) 1761 break; 1762 1763 decode_dmi((struct dmi_header *) dev->device_data, intf_num++); 1764 } 1765 } 1766 1767 static int try_init_smbios(int intf_num, struct smi_info **new_info) 1768 { 1769 struct smi_info *info; 1770 dmi_ipmi_data_t *ipmi_data = dmi_data+intf_num; 1771 char *io_type; 1772 1773 if (intf_num >= dmi_data_entries) 1774 return -ENODEV; 1775 1776 switch (ipmi_data->type) { 1777 case 0x01: /* KCS */ 1778 si_type[intf_num] = "kcs"; 1779 break; 1780 case 0x02: /* SMIC */ 1781 si_type[intf_num] = "smic"; 1782 break; 1783 case 0x03: /* BT */ 1784 si_type[intf_num] = "bt"; 1785 break; 1786 default: 1787 return -EIO; 1788 } 1789 1790 info = kmalloc(sizeof(*info), GFP_KERNEL); 1791 if (! info) { 1792 printk(KERN_ERR "ipmi_si: Could not allocate SI data (4)\n"); 1793 return -ENOMEM; 1794 } 1795 memset(info, 0, sizeof(*info)); 1796 1797 if (ipmi_data->addr_space == 1) { 1798 io_type = "memory"; 1799 info->io_setup = mem_setup; 1800 addrs[intf_num] = ipmi_data->base_addr; 1801 info->io.info = &(addrs[intf_num]); 1802 } else if (ipmi_data->addr_space == 2) { 1803 io_type = "I/O"; 1804 info->io_setup = port_setup; 1805 ports[intf_num] = ipmi_data->base_addr; 1806 info->io.info = &(ports[intf_num]); 1807 } else { 1808 kfree(info); 1809 printk("ipmi_si: Unknown SMBIOS I/O Address type.\n"); 1810 return -EIO; 1811 } 1812 1813 regspacings[intf_num] = ipmi_data->offset; 1814 info->io.regspacing = regspacings[intf_num]; 1815 if (! info->io.regspacing) 1816 info->io.regspacing = DEFAULT_REGSPACING; 1817 info->io.regsize = DEFAULT_REGSPACING; 1818 info->io.regshift = regshifts[intf_num]; 1819 1820 info->slave_addr = ipmi_data->slave_addr; 1821 1822 irqs[intf_num] = ipmi_data->irq; 1823 1824 *new_info = info; 1825 1826 printk("ipmi_si: Found SMBIOS-specified state machine at %s" 1827 " address 0x%lx, slave address 0x%x\n", 1828 io_type, (unsigned long)ipmi_data->base_addr, 1829 ipmi_data->slave_addr); 1830 return 0; 1831 } 1832 #endif /* CONFIG_X86 */ 1833 1834 #ifdef CONFIG_PCI 1835 1836 #define PCI_ERMC_CLASSCODE 0x0C0700 1837 #define PCI_HP_VENDOR_ID 0x103C 1838 #define PCI_MMC_DEVICE_ID 0x121A 1839 #define PCI_MMC_ADDR_CW 0x10 1840 1841 /* Avoid more than one attempt to probe pci smic. */ 1842 static int pci_smic_checked = 0; 1843 1844 static int find_pci_smic(int intf_num, struct smi_info **new_info) 1845 { 1846 struct smi_info *info; 1847 int error; 1848 struct pci_dev *pci_dev = NULL; 1849 u16 base_addr; 1850 int fe_rmc = 0; 1851 1852 if (pci_smic_checked) 1853 return -ENODEV; 1854 1855 pci_smic_checked = 1; 1856 1857 pci_dev = pci_get_device(PCI_HP_VENDOR_ID, PCI_MMC_DEVICE_ID, NULL); 1858 if (! pci_dev) { 1859 pci_dev = pci_get_class(PCI_ERMC_CLASSCODE, NULL); 1860 if (pci_dev && (pci_dev->subsystem_vendor == PCI_HP_VENDOR_ID)) 1861 fe_rmc = 1; 1862 else 1863 return -ENODEV; 1864 } 1865 1866 error = pci_read_config_word(pci_dev, PCI_MMC_ADDR_CW, &base_addr); 1867 if (error) 1868 { 1869 pci_dev_put(pci_dev); 1870 printk(KERN_ERR 1871 "ipmi_si: pci_read_config_word() failed (%d).\n", 1872 error); 1873 return -ENODEV; 1874 } 1875 1876 /* Bit 0: 1 specifies programmed I/O, 0 specifies memory mapped I/O */ 1877 if (! (base_addr & 0x0001)) 1878 { 1879 pci_dev_put(pci_dev); 1880 printk(KERN_ERR 1881 "ipmi_si: memory mapped I/O not supported for PCI" 1882 " smic.\n"); 1883 return -ENODEV; 1884 } 1885 1886 base_addr &= 0xFFFE; 1887 if (! fe_rmc) 1888 /* Data register starts at base address + 1 in eRMC */ 1889 ++base_addr; 1890 1891 if (! is_new_interface(-1, IPMI_IO_ADDR_SPACE, base_addr)) { 1892 pci_dev_put(pci_dev); 1893 return -ENODEV; 1894 } 1895 1896 info = kmalloc(sizeof(*info), GFP_KERNEL); 1897 if (! info) { 1898 pci_dev_put(pci_dev); 1899 printk(KERN_ERR "ipmi_si: Could not allocate SI data (5)\n"); 1900 return -ENOMEM; 1901 } 1902 memset(info, 0, sizeof(*info)); 1903 1904 info->io_setup = port_setup; 1905 ports[intf_num] = base_addr; 1906 info->io.info = &(ports[intf_num]); 1907 info->io.regspacing = regspacings[intf_num]; 1908 if (! info->io.regspacing) 1909 info->io.regspacing = DEFAULT_REGSPACING; 1910 info->io.regsize = DEFAULT_REGSPACING; 1911 info->io.regshift = regshifts[intf_num]; 1912 1913 *new_info = info; 1914 1915 irqs[intf_num] = pci_dev->irq; 1916 si_type[intf_num] = "smic"; 1917 1918 printk("ipmi_si: Found PCI SMIC at I/O address 0x%lx\n", 1919 (long unsigned int) base_addr); 1920 1921 pci_dev_put(pci_dev); 1922 return 0; 1923 } 1924 #endif /* CONFIG_PCI */ 1925 1926 static int try_init_plug_and_play(int intf_num, struct smi_info **new_info) 1927 { 1928 #ifdef CONFIG_PCI 1929 if (find_pci_smic(intf_num, new_info) == 0) 1930 return 0; 1931 #endif 1932 /* Include other methods here. */ 1933 1934 return -ENODEV; 1935 } 1936 1937 1938 static int try_get_dev_id(struct smi_info *smi_info) 1939 { 1940 unsigned char msg[2]; 1941 unsigned char *resp; 1942 unsigned long resp_len; 1943 enum si_sm_result smi_result; 1944 int rv = 0; 1945 1946 resp = kmalloc(IPMI_MAX_MSG_LENGTH, GFP_KERNEL); 1947 if (! resp) 1948 return -ENOMEM; 1949 1950 /* Do a Get Device ID command, since it comes back with some 1951 useful info. */ 1952 msg[0] = IPMI_NETFN_APP_REQUEST << 2; 1953 msg[1] = IPMI_GET_DEVICE_ID_CMD; 1954 smi_info->handlers->start_transaction(smi_info->si_sm, msg, 2); 1955 1956 smi_result = smi_info->handlers->event(smi_info->si_sm, 0); 1957 for (;;) 1958 { 1959 if (smi_result == SI_SM_CALL_WITH_DELAY || 1960 smi_result == SI_SM_CALL_WITH_TICK_DELAY) { 1961 schedule_timeout_uninterruptible(1); 1962 smi_result = smi_info->handlers->event( 1963 smi_info->si_sm, 100); 1964 } 1965 else if (smi_result == SI_SM_CALL_WITHOUT_DELAY) 1966 { 1967 smi_result = smi_info->handlers->event( 1968 smi_info->si_sm, 0); 1969 } 1970 else 1971 break; 1972 } 1973 if (smi_result == SI_SM_HOSED) { 1974 /* We couldn't get the state machine to run, so whatever's at 1975 the port is probably not an IPMI SMI interface. */ 1976 rv = -ENODEV; 1977 goto out; 1978 } 1979 1980 /* Otherwise, we got some data. */ 1981 resp_len = smi_info->handlers->get_result(smi_info->si_sm, 1982 resp, IPMI_MAX_MSG_LENGTH); 1983 if (resp_len < 6) { 1984 /* That's odd, it should be longer. */ 1985 rv = -EINVAL; 1986 goto out; 1987 } 1988 1989 if ((resp[1] != IPMI_GET_DEVICE_ID_CMD) || (resp[2] != 0)) { 1990 /* That's odd, it shouldn't be able to fail. */ 1991 rv = -EINVAL; 1992 goto out; 1993 } 1994 1995 /* Record info from the get device id, in case we need it. */ 1996 memcpy(&smi_info->device_id, &resp[3], 1997 min_t(unsigned long, resp_len-3, sizeof(smi_info->device_id))); 1998 1999 out: 2000 kfree(resp); 2001 return rv; 2002 } 2003 2004 static int type_file_read_proc(char *page, char **start, off_t off, 2005 int count, int *eof, void *data) 2006 { 2007 char *out = (char *) page; 2008 struct smi_info *smi = data; 2009 2010 switch (smi->si_type) { 2011 case SI_KCS: 2012 return sprintf(out, "kcs\n"); 2013 case SI_SMIC: 2014 return sprintf(out, "smic\n"); 2015 case SI_BT: 2016 return sprintf(out, "bt\n"); 2017 default: 2018 return 0; 2019 } 2020 } 2021 2022 static int stat_file_read_proc(char *page, char **start, off_t off, 2023 int count, int *eof, void *data) 2024 { 2025 char *out = (char *) page; 2026 struct smi_info *smi = data; 2027 2028 out += sprintf(out, "interrupts_enabled: %d\n", 2029 smi->irq && ! smi->interrupt_disabled); 2030 out += sprintf(out, "short_timeouts: %ld\n", 2031 smi->short_timeouts); 2032 out += sprintf(out, "long_timeouts: %ld\n", 2033 smi->long_timeouts); 2034 out += sprintf(out, "timeout_restarts: %ld\n", 2035 smi->timeout_restarts); 2036 out += sprintf(out, "idles: %ld\n", 2037 smi->idles); 2038 out += sprintf(out, "interrupts: %ld\n", 2039 smi->interrupts); 2040 out += sprintf(out, "attentions: %ld\n", 2041 smi->attentions); 2042 out += sprintf(out, "flag_fetches: %ld\n", 2043 smi->flag_fetches); 2044 out += sprintf(out, "hosed_count: %ld\n", 2045 smi->hosed_count); 2046 out += sprintf(out, "complete_transactions: %ld\n", 2047 smi->complete_transactions); 2048 out += sprintf(out, "events: %ld\n", 2049 smi->events); 2050 out += sprintf(out, "watchdog_pretimeouts: %ld\n", 2051 smi->watchdog_pretimeouts); 2052 out += sprintf(out, "incoming_messages: %ld\n", 2053 smi->incoming_messages); 2054 2055 return (out - ((char *) page)); 2056 } 2057 2058 /* 2059 * oem_data_avail_to_receive_msg_avail 2060 * @info - smi_info structure with msg_flags set 2061 * 2062 * Converts flags from OEM_DATA_AVAIL to RECEIVE_MSG_AVAIL 2063 * Returns 1 indicating need to re-run handle_flags(). 2064 */ 2065 static int oem_data_avail_to_receive_msg_avail(struct smi_info *smi_info) 2066 { 2067 smi_info->msg_flags = ((smi_info->msg_flags & ~OEM_DATA_AVAIL) | 2068 RECEIVE_MSG_AVAIL); 2069 return 1; 2070 } 2071 2072 /* 2073 * setup_dell_poweredge_oem_data_handler 2074 * @info - smi_info.device_id must be populated 2075 * 2076 * Systems that match, but have firmware version < 1.40 may assert 2077 * OEM0_DATA_AVAIL on their own, without being told via Set Flags that 2078 * it's safe to do so. Such systems will de-assert OEM1_DATA_AVAIL 2079 * upon receipt of IPMI_GET_MSG_CMD, so we should treat these flags 2080 * as RECEIVE_MSG_AVAIL instead. 2081 * 2082 * As Dell has no plans to release IPMI 1.5 firmware that *ever* 2083 * assert the OEM[012] bits, and if it did, the driver would have to 2084 * change to handle that properly, we don't actually check for the 2085 * firmware version. 2086 * Device ID = 0x20 BMC on PowerEdge 8G servers 2087 * Device Revision = 0x80 2088 * Firmware Revision1 = 0x01 BMC version 1.40 2089 * Firmware Revision2 = 0x40 BCD encoded 2090 * IPMI Version = 0x51 IPMI 1.5 2091 * Manufacturer ID = A2 02 00 Dell IANA 2092 * 2093 * Additionally, PowerEdge systems with IPMI < 1.5 may also assert 2094 * OEM0_DATA_AVAIL and needs to be treated as RECEIVE_MSG_AVAIL. 2095 * 2096 */ 2097 #define DELL_POWEREDGE_8G_BMC_DEVICE_ID 0x20 2098 #define DELL_POWEREDGE_8G_BMC_DEVICE_REV 0x80 2099 #define DELL_POWEREDGE_8G_BMC_IPMI_VERSION 0x51 2100 #define DELL_IANA_MFR_ID {0xA2, 0x02, 0x00} 2101 static void setup_dell_poweredge_oem_data_handler(struct smi_info *smi_info) 2102 { 2103 struct ipmi_device_id *id = &smi_info->device_id; 2104 const char mfr[3]=DELL_IANA_MFR_ID; 2105 if (! memcmp(mfr, id->manufacturer_id, sizeof(mfr))) { 2106 if (id->device_id == DELL_POWEREDGE_8G_BMC_DEVICE_ID && 2107 id->device_revision == DELL_POWEREDGE_8G_BMC_DEVICE_REV && 2108 id->ipmi_version == DELL_POWEREDGE_8G_BMC_IPMI_VERSION) { 2109 smi_info->oem_data_avail_handler = 2110 oem_data_avail_to_receive_msg_avail; 2111 } 2112 else if (ipmi_version_major(id) < 1 || 2113 (ipmi_version_major(id) == 1 && 2114 ipmi_version_minor(id) < 5)) { 2115 smi_info->oem_data_avail_handler = 2116 oem_data_avail_to_receive_msg_avail; 2117 } 2118 } 2119 } 2120 2121 #define CANNOT_RETURN_REQUESTED_LENGTH 0xCA 2122 static void return_hosed_msg_badsize(struct smi_info *smi_info) 2123 { 2124 struct ipmi_smi_msg *msg = smi_info->curr_msg; 2125 2126 /* Make it a reponse */ 2127 msg->rsp[0] = msg->data[0] | 4; 2128 msg->rsp[1] = msg->data[1]; 2129 msg->rsp[2] = CANNOT_RETURN_REQUESTED_LENGTH; 2130 msg->rsp_size = 3; 2131 smi_info->curr_msg = NULL; 2132 deliver_recv_msg(smi_info, msg); 2133 } 2134 2135 /* 2136 * dell_poweredge_bt_xaction_handler 2137 * @info - smi_info.device_id must be populated 2138 * 2139 * Dell PowerEdge servers with the BT interface (x6xx and 1750) will 2140 * not respond to a Get SDR command if the length of the data 2141 * requested is exactly 0x3A, which leads to command timeouts and no 2142 * data returned. This intercepts such commands, and causes userspace 2143 * callers to try again with a different-sized buffer, which succeeds. 2144 */ 2145 2146 #define STORAGE_NETFN 0x0A 2147 #define STORAGE_CMD_GET_SDR 0x23 2148 static int dell_poweredge_bt_xaction_handler(struct notifier_block *self, 2149 unsigned long unused, 2150 void *in) 2151 { 2152 struct smi_info *smi_info = in; 2153 unsigned char *data = smi_info->curr_msg->data; 2154 unsigned int size = smi_info->curr_msg->data_size; 2155 if (size >= 8 && 2156 (data[0]>>2) == STORAGE_NETFN && 2157 data[1] == STORAGE_CMD_GET_SDR && 2158 data[7] == 0x3A) { 2159 return_hosed_msg_badsize(smi_info); 2160 return NOTIFY_STOP; 2161 } 2162 return NOTIFY_DONE; 2163 } 2164 2165 static struct notifier_block dell_poweredge_bt_xaction_notifier = { 2166 .notifier_call = dell_poweredge_bt_xaction_handler, 2167 }; 2168 2169 /* 2170 * setup_dell_poweredge_bt_xaction_handler 2171 * @info - smi_info.device_id must be filled in already 2172 * 2173 * Fills in smi_info.device_id.start_transaction_pre_hook 2174 * when we know what function to use there. 2175 */ 2176 static void 2177 setup_dell_poweredge_bt_xaction_handler(struct smi_info *smi_info) 2178 { 2179 struct ipmi_device_id *id = &smi_info->device_id; 2180 const char mfr[3]=DELL_IANA_MFR_ID; 2181 if (! memcmp(mfr, id->manufacturer_id, sizeof(mfr)) && 2182 smi_info->si_type == SI_BT) 2183 register_xaction_notifier(&dell_poweredge_bt_xaction_notifier); 2184 } 2185 2186 /* 2187 * setup_oem_data_handler 2188 * @info - smi_info.device_id must be filled in already 2189 * 2190 * Fills in smi_info.device_id.oem_data_available_handler 2191 * when we know what function to use there. 2192 */ 2193 2194 static void setup_oem_data_handler(struct smi_info *smi_info) 2195 { 2196 setup_dell_poweredge_oem_data_handler(smi_info); 2197 } 2198 2199 static void setup_xaction_handlers(struct smi_info *smi_info) 2200 { 2201 setup_dell_poweredge_bt_xaction_handler(smi_info); 2202 } 2203 2204 static inline void wait_for_timer_and_thread(struct smi_info *smi_info) 2205 { 2206 if (smi_info->thread != NULL && smi_info->thread != ERR_PTR(-ENOMEM)) 2207 kthread_stop(smi_info->thread); 2208 del_timer_sync(&smi_info->si_timer); 2209 } 2210 2211 /* Returns 0 if initialized, or negative on an error. */ 2212 static int init_one_smi(int intf_num, struct smi_info **smi) 2213 { 2214 int rv; 2215 struct smi_info *new_smi; 2216 2217 2218 rv = try_init_mem(intf_num, &new_smi); 2219 if (rv) 2220 rv = try_init_port(intf_num, &new_smi); 2221 #ifdef CONFIG_ACPI 2222 if (rv && si_trydefaults) 2223 rv = try_init_acpi(intf_num, &new_smi); 2224 #endif 2225 #ifdef CONFIG_X86 2226 if (rv && si_trydefaults) 2227 rv = try_init_smbios(intf_num, &new_smi); 2228 #endif 2229 if (rv && si_trydefaults) 2230 rv = try_init_plug_and_play(intf_num, &new_smi); 2231 2232 if (rv) 2233 return rv; 2234 2235 /* So we know not to free it unless we have allocated one. */ 2236 new_smi->intf = NULL; 2237 new_smi->si_sm = NULL; 2238 new_smi->handlers = NULL; 2239 2240 if (! new_smi->irq_setup) { 2241 new_smi->irq = irqs[intf_num]; 2242 new_smi->irq_setup = std_irq_setup; 2243 new_smi->irq_cleanup = std_irq_cleanup; 2244 } 2245 2246 /* Default to KCS if no type is specified. */ 2247 if (si_type[intf_num] == NULL) { 2248 if (si_trydefaults) 2249 si_type[intf_num] = "kcs"; 2250 else { 2251 rv = -EINVAL; 2252 goto out_err; 2253 } 2254 } 2255 2256 /* Set up the state machine to use. */ 2257 if (strcmp(si_type[intf_num], "kcs") == 0) { 2258 new_smi->handlers = &kcs_smi_handlers; 2259 new_smi->si_type = SI_KCS; 2260 } else if (strcmp(si_type[intf_num], "smic") == 0) { 2261 new_smi->handlers = &smic_smi_handlers; 2262 new_smi->si_type = SI_SMIC; 2263 } else if (strcmp(si_type[intf_num], "bt") == 0) { 2264 new_smi->handlers = &bt_smi_handlers; 2265 new_smi->si_type = SI_BT; 2266 } else { 2267 /* No support for anything else yet. */ 2268 rv = -EIO; 2269 goto out_err; 2270 } 2271 2272 /* Allocate the state machine's data and initialize it. */ 2273 new_smi->si_sm = kmalloc(new_smi->handlers->size(), GFP_KERNEL); 2274 if (! new_smi->si_sm) { 2275 printk(" Could not allocate state machine memory\n"); 2276 rv = -ENOMEM; 2277 goto out_err; 2278 } 2279 new_smi->io_size = new_smi->handlers->init_data(new_smi->si_sm, 2280 &new_smi->io); 2281 2282 /* Now that we know the I/O size, we can set up the I/O. */ 2283 rv = new_smi->io_setup(new_smi); 2284 if (rv) { 2285 printk(" Could not set up I/O space\n"); 2286 goto out_err; 2287 } 2288 2289 spin_lock_init(&(new_smi->si_lock)); 2290 spin_lock_init(&(new_smi->msg_lock)); 2291 spin_lock_init(&(new_smi->count_lock)); 2292 2293 /* Do low-level detection first. */ 2294 if (new_smi->handlers->detect(new_smi->si_sm)) { 2295 rv = -ENODEV; 2296 goto out_err; 2297 } 2298 2299 /* Attempt a get device id command. If it fails, we probably 2300 don't have a SMI here. */ 2301 rv = try_get_dev_id(new_smi); 2302 if (rv) 2303 goto out_err; 2304 2305 setup_oem_data_handler(new_smi); 2306 setup_xaction_handlers(new_smi); 2307 2308 /* Try to claim any interrupts. */ 2309 new_smi->irq_setup(new_smi); 2310 2311 INIT_LIST_HEAD(&(new_smi->xmit_msgs)); 2312 INIT_LIST_HEAD(&(new_smi->hp_xmit_msgs)); 2313 new_smi->curr_msg = NULL; 2314 atomic_set(&new_smi->req_events, 0); 2315 new_smi->run_to_completion = 0; 2316 2317 new_smi->interrupt_disabled = 0; 2318 atomic_set(&new_smi->stop_operation, 0); 2319 new_smi->intf_num = intf_num; 2320 2321 /* Start clearing the flags before we enable interrupts or the 2322 timer to avoid racing with the timer. */ 2323 start_clear_flags(new_smi); 2324 /* IRQ is defined to be set when non-zero. */ 2325 if (new_smi->irq) 2326 new_smi->si_state = SI_CLEARING_FLAGS_THEN_SET_IRQ; 2327 2328 /* The ipmi_register_smi() code does some operations to 2329 determine the channel information, so we must be ready to 2330 handle operations before it is called. This means we have 2331 to stop the timer if we get an error after this point. */ 2332 init_timer(&(new_smi->si_timer)); 2333 new_smi->si_timer.data = (long) new_smi; 2334 new_smi->si_timer.function = smi_timeout; 2335 new_smi->last_timeout_jiffies = jiffies; 2336 new_smi->si_timer.expires = jiffies + SI_TIMEOUT_JIFFIES; 2337 2338 add_timer(&(new_smi->si_timer)); 2339 if (new_smi->si_type != SI_BT) 2340 new_smi->thread = kthread_run(ipmi_thread, new_smi, 2341 "kipmi%d", new_smi->intf_num); 2342 2343 rv = ipmi_register_smi(&handlers, 2344 new_smi, 2345 ipmi_version_major(&new_smi->device_id), 2346 ipmi_version_minor(&new_smi->device_id), 2347 new_smi->slave_addr, 2348 &(new_smi->intf)); 2349 if (rv) { 2350 printk(KERN_ERR 2351 "ipmi_si: Unable to register device: error %d\n", 2352 rv); 2353 goto out_err_stop_timer; 2354 } 2355 2356 rv = ipmi_smi_add_proc_entry(new_smi->intf, "type", 2357 type_file_read_proc, NULL, 2358 new_smi, THIS_MODULE); 2359 if (rv) { 2360 printk(KERN_ERR 2361 "ipmi_si: Unable to create proc entry: %d\n", 2362 rv); 2363 goto out_err_stop_timer; 2364 } 2365 2366 rv = ipmi_smi_add_proc_entry(new_smi->intf, "si_stats", 2367 stat_file_read_proc, NULL, 2368 new_smi, THIS_MODULE); 2369 if (rv) { 2370 printk(KERN_ERR 2371 "ipmi_si: Unable to create proc entry: %d\n", 2372 rv); 2373 goto out_err_stop_timer; 2374 } 2375 2376 *smi = new_smi; 2377 2378 printk(" IPMI %s interface initialized\n", si_type[intf_num]); 2379 2380 return 0; 2381 2382 out_err_stop_timer: 2383 atomic_inc(&new_smi->stop_operation); 2384 wait_for_timer_and_thread(new_smi); 2385 2386 out_err: 2387 if (new_smi->intf) 2388 ipmi_unregister_smi(new_smi->intf); 2389 2390 new_smi->irq_cleanup(new_smi); 2391 2392 /* Wait until we know that we are out of any interrupt 2393 handlers might have been running before we freed the 2394 interrupt. */ 2395 synchronize_sched(); 2396 2397 if (new_smi->si_sm) { 2398 if (new_smi->handlers) 2399 new_smi->handlers->cleanup(new_smi->si_sm); 2400 kfree(new_smi->si_sm); 2401 } 2402 if (new_smi->io_cleanup) 2403 new_smi->io_cleanup(new_smi); 2404 2405 return rv; 2406 } 2407 2408 static __init int init_ipmi_si(void) 2409 { 2410 int rv = 0; 2411 int pos = 0; 2412 int i; 2413 char *str; 2414 2415 if (initialized) 2416 return 0; 2417 initialized = 1; 2418 2419 /* Parse out the si_type string into its components. */ 2420 str = si_type_str; 2421 if (*str != '\0') { 2422 for (i = 0; (i < SI_MAX_PARMS) && (*str != '\0'); i++) { 2423 si_type[i] = str; 2424 str = strchr(str, ','); 2425 if (str) { 2426 *str = '\0'; 2427 str++; 2428 } else { 2429 break; 2430 } 2431 } 2432 } 2433 2434 printk(KERN_INFO "IPMI System Interface driver.\n"); 2435 2436 #ifdef CONFIG_X86 2437 dmi_find_bmc(); 2438 #endif 2439 2440 rv = init_one_smi(0, &(smi_infos[pos])); 2441 if (rv && ! ports[0] && si_trydefaults) { 2442 /* If we are trying defaults and the initial port is 2443 not set, then set it. */ 2444 si_type[0] = "kcs"; 2445 ports[0] = DEFAULT_KCS_IO_PORT; 2446 rv = init_one_smi(0, &(smi_infos[pos])); 2447 if (rv) { 2448 /* No KCS - try SMIC */ 2449 si_type[0] = "smic"; 2450 ports[0] = DEFAULT_SMIC_IO_PORT; 2451 rv = init_one_smi(0, &(smi_infos[pos])); 2452 } 2453 if (rv) { 2454 /* No SMIC - try BT */ 2455 si_type[0] = "bt"; 2456 ports[0] = DEFAULT_BT_IO_PORT; 2457 rv = init_one_smi(0, &(smi_infos[pos])); 2458 } 2459 } 2460 if (rv == 0) 2461 pos++; 2462 2463 for (i = 1; i < SI_MAX_PARMS; i++) { 2464 rv = init_one_smi(i, &(smi_infos[pos])); 2465 if (rv == 0) 2466 pos++; 2467 } 2468 2469 if (smi_infos[0] == NULL) { 2470 printk("ipmi_si: Unable to find any System Interface(s)\n"); 2471 return -ENODEV; 2472 } 2473 2474 return 0; 2475 } 2476 module_init(init_ipmi_si); 2477 2478 static void __exit cleanup_one_si(struct smi_info *to_clean) 2479 { 2480 int rv; 2481 unsigned long flags; 2482 2483 if (! to_clean) 2484 return; 2485 2486 /* Tell the timer and interrupt handlers that we are shutting 2487 down. */ 2488 spin_lock_irqsave(&(to_clean->si_lock), flags); 2489 spin_lock(&(to_clean->msg_lock)); 2490 2491 atomic_inc(&to_clean->stop_operation); 2492 to_clean->irq_cleanup(to_clean); 2493 2494 spin_unlock(&(to_clean->msg_lock)); 2495 spin_unlock_irqrestore(&(to_clean->si_lock), flags); 2496 2497 /* Wait until we know that we are out of any interrupt 2498 handlers might have been running before we freed the 2499 interrupt. */ 2500 synchronize_sched(); 2501 2502 wait_for_timer_and_thread(to_clean); 2503 2504 /* Interrupts and timeouts are stopped, now make sure the 2505 interface is in a clean state. */ 2506 while (to_clean->curr_msg || (to_clean->si_state != SI_NORMAL)) { 2507 poll(to_clean); 2508 schedule_timeout_uninterruptible(1); 2509 } 2510 2511 rv = ipmi_unregister_smi(to_clean->intf); 2512 if (rv) { 2513 printk(KERN_ERR 2514 "ipmi_si: Unable to unregister device: errno=%d\n", 2515 rv); 2516 } 2517 2518 to_clean->handlers->cleanup(to_clean->si_sm); 2519 2520 kfree(to_clean->si_sm); 2521 2522 if (to_clean->io_cleanup) 2523 to_clean->io_cleanup(to_clean); 2524 } 2525 2526 static __exit void cleanup_ipmi_si(void) 2527 { 2528 int i; 2529 2530 if (! initialized) 2531 return; 2532 2533 for (i = 0; i < SI_MAX_DRIVERS; i++) { 2534 cleanup_one_si(smi_infos[i]); 2535 } 2536 } 2537 module_exit(cleanup_ipmi_si); 2538 2539 MODULE_LICENSE("GPL"); 2540 MODULE_AUTHOR("Corey Minyard <minyard@mvista.com>"); 2541 MODULE_DESCRIPTION("Interface to the IPMI driver for the KCS, SMIC, and BT system interfaces."); 2542