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[/] [or1k/] [trunk/] [linux/] [linux-2.4/] [drivers/] [message/] [i2o/] [i2o_core.c] - Blame information for rev 1275

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1 1275 phoenix
/*
2
 * Core I2O structure management
3
 *
4
 * (C) Copyright 1999   Red Hat Software
5
 *
6
 * Written by Alan Cox, Building Number Three Ltd
7
 *
8
 * This program is free software; you can redistribute it and/or
9
 * modify it under the terms of the GNU General Public License
10
 * as published by the Free Software Foundation; either version
11
 * 2 of the License, or (at your option) any later version.
12
 *
13
 * A lot of the I2O message side code from this is taken from the
14
 * Red Creek RCPCI45 adapter driver by Red Creek Communications
15
 *
16
 * Fixes by:
17
 *              Philipp Rumpf
18
 *              Juha Sievänen <Juha.Sievanen@cs.Helsinki.FI>
19
 *              Auvo Häkkinen <Auvo.Hakkinen@cs.Helsinki.FI>
20
 *              Deepak Saxena <deepak@plexity.net>
21
 *              Boji T Kannanthanam <boji.t.kannanthanam@intel.com>
22
 *
23
 */
24
 
25
#include <linux/config.h>
26
#include <linux/module.h>
27
#include <linux/kernel.h>
28
#include <linux/pci.h>
29
 
30
#include <linux/i2o.h>
31
 
32
#include <linux/errno.h>
33
#include <linux/init.h>
34
#include <linux/slab.h>
35
#include <linux/spinlock.h>
36
#include <linux/smp_lock.h>
37
 
38
#include <linux/bitops.h>
39
#include <linux/wait.h>
40
#include <linux/delay.h>
41
#include <linux/timer.h>
42
#include <linux/tqueue.h>
43
#include <linux/interrupt.h>
44
#include <linux/sched.h>
45
#include <asm/semaphore.h>
46
#include <linux/completion.h>
47
 
48
#include <asm/io.h>
49
#include <linux/reboot.h>
50
 
51
#include "i2o_lan.h"
52
 
53
//#define DRIVERDEBUG
54
 
55
#ifdef DRIVERDEBUG
56
#define dprintk(s, args...) printk(s, ## args)
57
#else
58
#define dprintk(s, args...)
59
#endif
60
 
61
/* OSM table */
62
static struct i2o_handler *i2o_handlers[MAX_I2O_MODULES];
63
 
64
/* Controller list */
65
static struct i2o_controller *i2o_controllers[MAX_I2O_CONTROLLERS];
66
struct i2o_controller *i2o_controller_chain;
67
int i2o_num_controllers;
68
 
69
/* Initiator Context for Core message */
70
static int core_context;
71
 
72
/* Initialization && shutdown functions */
73
void i2o_sys_init(void);
74
static void i2o_sys_shutdown(void);
75
static int i2o_reset_controller(struct i2o_controller *);
76
static int i2o_reboot_event(struct notifier_block *, unsigned long , void *);
77
static int i2o_online_controller(struct i2o_controller *);
78
static int i2o_init_outbound_q(struct i2o_controller *);
79
static int i2o_post_outbound_messages(struct i2o_controller *);
80
 
81
/* Reply handler */
82
static void i2o_core_reply(struct i2o_handler *, struct i2o_controller *,
83
                           struct i2o_message *);
84
 
85
/* Various helper functions */
86
static int i2o_lct_get(struct i2o_controller *);
87
static int i2o_lct_notify(struct i2o_controller *);
88
static int i2o_hrt_get(struct i2o_controller *);
89
 
90
static int i2o_build_sys_table(void);
91
static int i2o_systab_send(struct i2o_controller *c);
92
 
93
/* I2O core event handler */
94
static int i2o_core_evt(void *);
95
static int evt_pid;
96
static int evt_running;
97
 
98
/* Dynamic LCT update handler */
99
static int i2o_dyn_lct(void *);
100
 
101
void i2o_report_controller_unit(struct i2o_controller *, struct i2o_device *);
102
 
103
/*
104
 * I2O System Table.  Contains information about
105
 * all the IOPs in the system.  Used to inform IOPs
106
 * about each other's existence.
107
 *
108
 * sys_tbl_ver is the CurrentChangeIndicator that is
109
 * used by IOPs to track changes.
110
 */
111
static struct i2o_sys_tbl *sys_tbl;
112
static int sys_tbl_ind;
113
static int sys_tbl_len;
114
 
115
/*
116
 * This spin lock is used to keep a device from being
117
 * added and deleted concurrently across CPUs or interrupts.
118
 * This can occur when a user creates a device and immediatelly
119
 * deletes it before the new_dev_notify() handler is called.
120
 */
121
static spinlock_t i2o_dev_lock = SPIN_LOCK_UNLOCKED;
122
 
123
/*
124
 * Structures and definitions for synchronous message posting.
125
 * See i2o_post_wait() for description.
126
 */
127
struct i2o_post_wait_data
128
{
129
        int *status;            /* Pointer to status block on caller stack */
130
        int *complete;          /* Pointer to completion flag on caller stack */
131
        u32 id;                 /* Unique identifier */
132
        wait_queue_head_t *wq;  /* Wake up for caller (NULL for dead) */
133
        struct i2o_post_wait_data *next;        /* Chain */
134
        void *mem[2];           /* Memory blocks to recover on failure path */
135
};
136
static struct i2o_post_wait_data *post_wait_queue;
137
static u32 post_wait_id;        // Unique ID for each post_wait
138
static spinlock_t post_wait_lock = SPIN_LOCK_UNLOCKED;
139
static void i2o_post_wait_complete(u32, int);
140
 
141
/* OSM descriptor handler */
142
static struct i2o_handler i2o_core_handler =
143
{
144
        (void *)i2o_core_reply,
145
        NULL,
146
        NULL,
147
        NULL,
148
        "I2O core layer",
149
        0,
150
        I2O_CLASS_EXECUTIVE
151
};
152
 
153
/*
154
 * Used when queueing a reply to be handled later
155
 */
156
 
157
struct reply_info
158
{
159
        struct i2o_controller *iop;
160
        u32 msg[MSG_FRAME_SIZE];
161
};
162
static struct reply_info evt_reply;
163
static struct reply_info events[I2O_EVT_Q_LEN];
164
static int evt_in;
165
static int evt_out;
166
static int evt_q_len;
167
#define MODINC(x,y) ((x) = ((x) + 1) % (y))
168
 
169
/*
170
 * I2O configuration spinlock. This isnt a big deal for contention
171
 * so we have one only
172
 */
173
 
174
static DECLARE_MUTEX(i2o_configuration_lock);
175
 
176
/*
177
 * Event spinlock.  Used to keep event queue sane and from
178
 * handling multiple events simultaneously.
179
 */
180
static spinlock_t i2o_evt_lock = SPIN_LOCK_UNLOCKED;
181
 
182
/*
183
 * Semaphore used to synchronize event handling thread with
184
 * interrupt handler.
185
 */
186
 
187
static DECLARE_MUTEX(evt_sem);
188
static DECLARE_COMPLETION(evt_dead);
189
static DECLARE_WAIT_QUEUE_HEAD(evt_wait);
190
 
191
static struct notifier_block i2o_reboot_notifier =
192
{
193
        i2o_reboot_event,
194
        NULL,
195
 
196
};
197
 
198
/*
199
 *      Config options
200
 */
201
 
202
static int verbose;
203
MODULE_PARM(verbose, "i");
204
 
205
/*
206
 * I2O Core reply handler
207
 */
208
static void i2o_core_reply(struct i2o_handler *h, struct i2o_controller *c,
209
                    struct i2o_message *m)
210
{
211
        u32 *msg=(u32 *)m;
212
        u32 status;
213
        u32 context = msg[2];
214
 
215
        if (msg[0] & MSG_FAIL) // Fail bit is set
216
        {
217
                u32 *preserved_msg = (u32*)(c->mem_offset + msg[7]);
218
 
219
                i2o_report_status(KERN_INFO, "i2o_core", msg);
220
                i2o_dump_message(preserved_msg);
221
 
222
                /* If the failed request needs special treatment,
223
                 * it should be done here. */
224
 
225
                /* Release the preserved msg by resubmitting it as a NOP */
226
 
227
                preserved_msg[0] = cpu_to_le32(THREE_WORD_MSG_SIZE | SGL_OFFSET_0);
228
                preserved_msg[1] = cpu_to_le32(I2O_CMD_UTIL_NOP << 24 | HOST_TID << 12 | 0);
229
                preserved_msg[2] = 0;
230
                i2o_post_message(c, msg[7]);
231
 
232
                /* If reply to i2o_post_wait failed, return causes a timeout */
233
 
234
                return;
235
        }
236
 
237
#ifdef DRIVERDEBUG
238
        i2o_report_status(KERN_INFO, "i2o_core", msg);
239
#endif
240
 
241
        if(msg[2]&0x80000000)   // Post wait message
242
        {
243
                if (msg[4] >> 24)
244
                        status = (msg[4] & 0xFFFF);
245
                else
246
                        status = I2O_POST_WAIT_OK;
247
 
248
                i2o_post_wait_complete(context, status);
249
                return;
250
        }
251
 
252
        if(m->function == I2O_CMD_UTIL_EVT_REGISTER)
253
        {
254
                memcpy(events[evt_in].msg, msg, (msg[0]>>16)<<2);
255
                events[evt_in].iop = c;
256
 
257
                spin_lock(&i2o_evt_lock);
258
                MODINC(evt_in, I2O_EVT_Q_LEN);
259
                if(evt_q_len == I2O_EVT_Q_LEN)
260
                        MODINC(evt_out, I2O_EVT_Q_LEN);
261
                else
262
                        evt_q_len++;
263
                spin_unlock(&i2o_evt_lock);
264
 
265
                up(&evt_sem);
266
                wake_up_interruptible(&evt_wait);
267
                return;
268
        }
269
 
270
        if(m->function == I2O_CMD_LCT_NOTIFY)
271
        {
272
                up(&c->lct_sem);
273
                return;
274
        }
275
 
276
        /*
277
         * If this happens, we want to dump the message to the syslog so
278
         * it can be sent back to the card manufacturer by the end user
279
         * to aid in debugging.
280
         *
281
         */
282
        printk(KERN_WARNING "%s: Unsolicited message reply sent to core!"
283
                        "Message dumped to syslog\n",
284
                        c->name);
285
        i2o_dump_message(msg);
286
 
287
        return;
288
}
289
 
290
/**
291
 *      i2o_install_handler - install a message handler
292
 *      @h: Handler structure
293
 *
294
 *      Install an I2O handler - these handle the asynchronous messaging
295
 *      from the card once it has initialised. If the table of handlers is
296
 *      full then -ENOSPC is returned. On a success 0 is returned and the
297
 *      context field is set by the function. The structure is part of the
298
 *      system from this time onwards. It must not be freed until it has
299
 *      been uninstalled
300
 */
301
 
302
int i2o_install_handler(struct i2o_handler *h)
303
{
304
        int i;
305
        down(&i2o_configuration_lock);
306
        for(i=0;i<MAX_I2O_MODULES;i++)
307
        {
308
                if(i2o_handlers[i]==NULL)
309
                {
310
                        h->context = i;
311
                        i2o_handlers[i]=h;
312
                        up(&i2o_configuration_lock);
313
                        return 0;
314
                }
315
        }
316
        up(&i2o_configuration_lock);
317
        return -ENOSPC;
318
}
319
 
320
/**
321
 *      i2o_remove_handler - remove an i2o message handler
322
 *      @h: handler
323
 *
324
 *      Remove a message handler previously installed with i2o_install_handler.
325
 *      After this function returns the handler object can be freed or re-used
326
 */
327
 
328
int i2o_remove_handler(struct i2o_handler *h)
329
{
330
        i2o_handlers[h->context]=NULL;
331
        return 0;
332
}
333
 
334
 
335
/*
336
 *      Each I2O controller has a chain of devices on it.
337
 * Each device has a pointer to it's LCT entry to be used
338
 * for fun purposes.
339
 */
340
 
341
/**
342
 *      i2o_install_device      -       attach a device to a controller
343
 *      @c: controller
344
 *      @d: device
345
 *
346
 *      Add a new device to an i2o controller. This can be called from
347
 *      non interrupt contexts only. It adds the device and marks it as
348
 *      unclaimed. The device memory becomes part of the kernel and must
349
 *      be uninstalled before being freed or reused. Zero is returned
350
 *      on success.
351
 */
352
 
353
int i2o_install_device(struct i2o_controller *c, struct i2o_device *d)
354
{
355
        int i;
356
 
357
        down(&i2o_configuration_lock);
358
        d->controller=c;
359
        d->owner=NULL;
360
        d->next=c->devices;
361
        d->prev=NULL;
362
        if (c->devices != NULL)
363
                c->devices->prev=d;
364
        c->devices=d;
365
        *d->dev_name = 0;
366
 
367
        for(i = 0; i < I2O_MAX_MANAGERS; i++)
368
                d->managers[i] = NULL;
369
 
370
        up(&i2o_configuration_lock);
371
        return 0;
372
}
373
 
374
/* we need this version to call out of i2o_delete_controller */
375
 
376
int __i2o_delete_device(struct i2o_device *d)
377
{
378
        struct i2o_device **p;
379
        int i;
380
 
381
        p=&(d->controller->devices);
382
 
383
        /*
384
         *      Hey we have a driver!
385
         * Check to see if the driver wants us to notify it of
386
         * device deletion. If it doesn't we assume that it
387
         * is unsafe to delete a device with an owner and
388
         * fail.
389
         */
390
        if(d->owner)
391
        {
392
                if(d->owner->dev_del_notify)
393
                {
394
                        dprintk(KERN_INFO "Device has owner, notifying\n");
395
                        d->owner->dev_del_notify(d->controller, d);
396
                        if(d->owner)
397
                        {
398
                                printk(KERN_WARNING
399
                                        "Driver \"%s\" did not release device!\n", d->owner->name);
400
                                return -EBUSY;
401
                        }
402
                }
403
                else
404
                        return -EBUSY;
405
        }
406
 
407
        /*
408
         * Tell any other users who are talking to this device
409
         * that it's going away.  We assume that everything works.
410
         */
411
        for(i=0; i < I2O_MAX_MANAGERS; i++)
412
        {
413
                if(d->managers[i] && d->managers[i]->dev_del_notify)
414
                        d->managers[i]->dev_del_notify(d->controller, d);
415
        }
416
 
417
        while(*p!=NULL)
418
        {
419
                if(*p==d)
420
                {
421
                        /*
422
                         *      Destroy
423
                         */
424
                        *p=d->next;
425
                        kfree(d);
426
                        return 0;
427
                }
428
                p=&((*p)->next);
429
        }
430
        printk(KERN_ERR "i2o_delete_device: passed invalid device.\n");
431
        return -EINVAL;
432
}
433
 
434
/**
435
 *      i2o_delete_device       -       remove an i2o device
436
 *      @d: device to remove
437
 *
438
 *      This function unhooks a device from a controller. The device
439
 *      will not be unhooked if it has an owner who does not wish to free
440
 *      it, or if the owner lacks a dev_del_notify function. In that case
441
 *      -EBUSY is returned. On success 0 is returned. Other errors cause
442
 *      negative errno values to be returned
443
 */
444
 
445
int i2o_delete_device(struct i2o_device *d)
446
{
447
        int ret;
448
 
449
        down(&i2o_configuration_lock);
450
 
451
        /*
452
         *      Seek, locate
453
         */
454
 
455
        ret = __i2o_delete_device(d);
456
 
457
        up(&i2o_configuration_lock);
458
 
459
        return ret;
460
}
461
 
462
/**
463
 *      i2o_install_controller  -       attach a controller
464
 *      @c: controller
465
 *
466
 *      Add a new controller to the i2o layer. This can be called from
467
 *      non interrupt contexts only. It adds the controller and marks it as
468
 *      unused with no devices. If the tables are full or memory allocations
469
 *      fail then a negative errno code is returned. On success zero is
470
 *      returned and the controller is bound to the system. The structure
471
 *      must not be freed or reused until being uninstalled.
472
 */
473
 
474
int i2o_install_controller(struct i2o_controller *c)
475
{
476
        int i;
477
        down(&i2o_configuration_lock);
478
        for(i=0;i<MAX_I2O_CONTROLLERS;i++)
479
        {
480
                if(i2o_controllers[i]==NULL)
481
                {
482
                        c->dlct = (i2o_lct*)kmalloc(8192, GFP_KERNEL);
483
                        if(c->dlct==NULL)
484
                        {
485
                                up(&i2o_configuration_lock);
486
                                return -ENOMEM;
487
                        }
488
                        i2o_controllers[i]=c;
489
                        c->devices = NULL;
490
                        c->next=i2o_controller_chain;
491
                        i2o_controller_chain=c;
492
                        c->unit = i;
493
                        c->page_frame = NULL;
494
                        c->hrt = NULL;
495
                        c->lct = NULL;
496
                        c->status_block = NULL;
497
                        sprintf(c->name, "i2o/iop%d", i);
498
                        i2o_num_controllers++;
499
                        init_MUTEX_LOCKED(&c->lct_sem);
500
                        up(&i2o_configuration_lock);
501
                        return 0;
502
                }
503
        }
504
        printk(KERN_ERR "No free i2o controller slots.\n");
505
        up(&i2o_configuration_lock);
506
        return -EBUSY;
507
}
508
 
509
/**
510
 *      i2o_delete_controller   - delete a controller
511
 *      @c: controller
512
 *
513
 *      Remove an i2o controller from the system. If the controller or its
514
 *      devices are busy then -EBUSY is returned. On a failure a negative
515
 *      errno code is returned. On success zero is returned.
516
 */
517
 
518
int i2o_delete_controller(struct i2o_controller *c)
519
{
520
        struct i2o_controller **p;
521
        int users;
522
        char name[16];
523
        int stat;
524
 
525
        dprintk(KERN_INFO "Deleting controller %s\n", c->name);
526
 
527
        /*
528
         * Clear event registration as this can cause weird behavior
529
         */
530
        if(c->status_block->iop_state == ADAPTER_STATE_OPERATIONAL)
531
                i2o_event_register(c, core_context, 0, 0, 0);
532
 
533
        down(&i2o_configuration_lock);
534
        if((users=atomic_read(&c->users)))
535
        {
536
                dprintk(KERN_INFO "I2O: %d users for controller %s\n", users,
537
                        c->name);
538
                up(&i2o_configuration_lock);
539
                return -EBUSY;
540
        }
541
        while(c->devices)
542
        {
543
                if(__i2o_delete_device(c->devices)<0)
544
                {
545
                        /* Shouldnt happen */
546
                        c->bus_disable(c);
547
                        up(&i2o_configuration_lock);
548
                        return -EBUSY;
549
                }
550
        }
551
 
552
        /*
553
         * If this is shutdown time, the thread's already been killed
554
         */
555
        if(c->lct_running) {
556
                stat = kill_proc(c->lct_pid, SIGTERM, 1);
557
                if(!stat) {
558
                        int count = 10 * 100;
559
                        while(c->lct_running && --count) {
560
                                current->state = TASK_INTERRUPTIBLE;
561
                                schedule_timeout(1);
562
                        }
563
 
564
                        if(!count)
565
                                printk(KERN_ERR
566
                                        "%s: LCT thread still running!\n",
567
                                        c->name);
568
                }
569
        }
570
 
571
        p=&i2o_controller_chain;
572
 
573
        while(*p)
574
        {
575
                if(*p==c)
576
                {
577
                        /* Ask the IOP to switch to RESET state */
578
                        i2o_reset_controller(c);
579
 
580
                        /* Release IRQ */
581
                        c->destructor(c);
582
 
583
                        *p=c->next;
584
                        up(&i2o_configuration_lock);
585
 
586
                        if(c->page_frame)
587
                        {
588
                                pci_unmap_single(c->pdev, c->page_frame_map, MSG_POOL_SIZE, PCI_DMA_FROMDEVICE);
589
                                kfree(c->page_frame);
590
                        }
591
                        if(c->hrt)
592
                                kfree(c->hrt);
593
                        if(c->lct)
594
                                kfree(c->lct);
595
                        if(c->status_block)
596
                                kfree(c->status_block);
597
                        if(c->dlct)
598
                                kfree(c->dlct);
599
 
600
                        i2o_controllers[c->unit]=NULL;
601
                        memcpy(name, c->name, strlen(c->name)+1);
602
                        kfree(c);
603
                        dprintk(KERN_INFO "%s: Deleted from controller chain.\n", name);
604
 
605
                        i2o_num_controllers--;
606
                        return 0;
607
                }
608
                p=&((*p)->next);
609
        }
610
        up(&i2o_configuration_lock);
611
        printk(KERN_ERR "i2o_delete_controller: bad pointer!\n");
612
        return -ENOENT;
613
}
614
 
615
/**
616
 *      i2o_unlock_controller   -       unlock a controller
617
 *      @c: controller to unlock
618
 *
619
 *      Take a lock on an i2o controller. This prevents it being deleted.
620
 *      i2o controllers are not refcounted so a deletion of an in use device
621
 *      will fail, not take affect on the last dereference.
622
 */
623
 
624
void i2o_unlock_controller(struct i2o_controller *c)
625
{
626
        atomic_dec(&c->users);
627
}
628
 
629
/**
630
 *      i2o_find_controller - return a locked controller
631
 *      @n: controller number
632
 *
633
 *      Returns a pointer to the controller object. The controller is locked
634
 *      on return. NULL is returned if the controller is not found.
635
 */
636
 
637
struct i2o_controller *i2o_find_controller(int n)
638
{
639
        struct i2o_controller *c;
640
 
641
        if(n<0 || n>=MAX_I2O_CONTROLLERS)
642
                return NULL;
643
 
644
        down(&i2o_configuration_lock);
645
        c=i2o_controllers[n];
646
        if(c!=NULL)
647
                atomic_inc(&c->users);
648
        up(&i2o_configuration_lock);
649
        return c;
650
}
651
 
652
/**
653
 *      i2o_issue_claim - claim or release a device
654
 *      @cmd: command
655
 *      @c: controller to claim for
656
 *      @tid: i2o task id
657
 *      @type: type of claim
658
 *
659
 *      Issue I2O UTIL_CLAIM and UTIL_RELEASE messages. The message to be sent
660
 *      is set by cmd. The tid is the task id of the object to claim and the
661
 *      type is the claim type (see the i2o standard)
662
 *
663
 *      Zero is returned on success.
664
 */
665
 
666
static int i2o_issue_claim(u32 cmd, struct i2o_controller *c, int tid, u32 type)
667
{
668
        u32 msg[5];
669
 
670
        msg[0] = FIVE_WORD_MSG_SIZE | SGL_OFFSET_0;
671
        msg[1] = cmd << 24 | HOST_TID<<12 | tid;
672
        msg[3] = 0;
673
        msg[4] = type;
674
 
675
        return i2o_post_wait(c, msg, sizeof(msg), 60);
676
}
677
 
678
/*
679
 *      i2o_claim_device - claim a device for use by an OSM
680
 *      @d: device to claim
681
 *      @h: handler for this device
682
 *
683
 *      Do the leg work to assign a device to a given OSM on Linux. The
684
 *      kernel updates the internal handler data for the device and then
685
 *      performs an I2O claim for the device, attempting to claim the
686
 *      device as primary. If the attempt fails a negative errno code
687
 *      is returned. On success zero is returned.
688
 */
689
 
690
int i2o_claim_device(struct i2o_device *d, struct i2o_handler *h)
691
{
692
        down(&i2o_configuration_lock);
693
        if (d->owner) {
694
                printk(KERN_INFO "Device claim called, but dev already owned by %s!",
695
                       h->name);
696
                up(&i2o_configuration_lock);
697
                return -EBUSY;
698
        }
699
        d->owner=h;
700
 
701
        if(i2o_issue_claim(I2O_CMD_UTIL_CLAIM ,d->controller,d->lct_data.tid,
702
                           I2O_CLAIM_PRIMARY))
703
        {
704
                d->owner = NULL;
705
                return -EBUSY;
706
        }
707
        up(&i2o_configuration_lock);
708
        return 0;
709
}
710
 
711
/**
712
 *      i2o_release_device - release a device that the OSM is using
713
 *      @d: device to claim
714
 *      @h: handler for this device
715
 *
716
 *      Drop a claim by an OSM on a given I2O device. The handler is cleared
717
 *      and 0 is returned on success.
718
 *
719
 *      AC - some devices seem to want to refuse an unclaim until they have
720
 *      finished internal processing. It makes sense since you don't want a
721
 *      new device to go reconfiguring the entire system until you are done.
722
 *      Thus we are prepared to wait briefly.
723
 */
724
 
725
int i2o_release_device(struct i2o_device *d, struct i2o_handler *h)
726
{
727
        int err = 0;
728
        int tries;
729
 
730
        down(&i2o_configuration_lock);
731
        if (d->owner != h) {
732
                printk(KERN_INFO "Claim release called, but not owned by %s!\n",
733
                       h->name);
734
                up(&i2o_configuration_lock);
735
                return -ENOENT;
736
        }
737
 
738
        for(tries=0;tries<10;tries++)
739
        {
740
                d->owner = NULL;
741
 
742
                /*
743
                 *      If the controller takes a nonblocking approach to
744
                 *      releases we have to sleep/poll for a few times.
745
                 */
746
 
747
                if((err=i2o_issue_claim(I2O_CMD_UTIL_RELEASE, d->controller, d->lct_data.tid, I2O_CLAIM_PRIMARY)) )
748
                {
749
                        err = -ENXIO;
750
                        current->state = TASK_UNINTERRUPTIBLE;
751
                        schedule_timeout(HZ);
752
                }
753
                else
754
                {
755
                        err=0;
756
                        break;
757
                }
758
        }
759
        up(&i2o_configuration_lock);
760
        return err;
761
}
762
 
763
/**
764
 *      i2o_device_notify_on    -       Enable deletion notifiers
765
 *      @d: device for notification
766
 *      @h: handler to install
767
 *
768
 *      Called by OSMs to let the core know that they want to be
769
 *      notified if the given device is deleted from the system.
770
 */
771
 
772
int i2o_device_notify_on(struct i2o_device *d, struct i2o_handler *h)
773
{
774
        int i;
775
 
776
        if(d->num_managers == I2O_MAX_MANAGERS)
777
                return -ENOSPC;
778
 
779
        for(i = 0; i < I2O_MAX_MANAGERS; i++)
780
        {
781
                if(!d->managers[i])
782
                {
783
                        d->managers[i] = h;
784
                        break;
785
                }
786
        }
787
 
788
        d->num_managers++;
789
 
790
        return 0;
791
}
792
 
793
/**
794
 *      i2o_device_notify_off   -       Remove deletion notifiers
795
 *      @d: device for notification
796
 *      @h: handler to remove
797
 *
798
 * Called by OSMs to let the core know that they no longer
799
 * are interested in the fate of the given device.
800
 */
801
int i2o_device_notify_off(struct i2o_device *d, struct i2o_handler *h)
802
{
803
        int i;
804
 
805
        for(i=0; i < I2O_MAX_MANAGERS; i++)
806
        {
807
                if(d->managers[i] == h)
808
                {
809
                        d->managers[i] = NULL;
810
                        d->num_managers--;
811
                        return 0;
812
                }
813
        }
814
 
815
        return -ENOENT;
816
}
817
 
818
/**
819
 *      i2o_event_register      -       register interest in an event
820
 *      @c: Controller to register interest with
821
 *      @tid: I2O task id
822
 *      @init_context: initiator context to use with this notifier
823
 *      @tr_context: transaction context to use with this notifier
824
 *      @evt_mask: mask of events
825
 *
826
 *      Create and posts an event registration message to the task. No reply
827
 *      is waited for, or expected. Errors in posting will be reported.
828
 */
829
 
830
int i2o_event_register(struct i2o_controller *c, u32 tid,
831
                u32 init_context, u32 tr_context, u32 evt_mask)
832
{
833
        u32 msg[5];     // Not performance critical, so we just 
834
                        // i2o_post_this it instead of building it
835
                        // in IOP memory
836
 
837
        msg[0] = FIVE_WORD_MSG_SIZE|SGL_OFFSET_0;
838
        msg[1] = I2O_CMD_UTIL_EVT_REGISTER<<24 | HOST_TID<<12 | tid;
839
        msg[2] = init_context;
840
        msg[3] = tr_context;
841
        msg[4] = evt_mask;
842
 
843
        return i2o_post_this(c, msg, sizeof(msg));
844
}
845
 
846
/*
847
 *      i2o_event_ack   -       acknowledge an event
848
 *      @c: controller
849
 *      @msg: pointer to the UTIL_EVENT_REGISTER reply we received
850
 *
851
 *      We just take a pointer to the original UTIL_EVENT_REGISTER reply
852
 *      message and change the function code since that's what spec
853
 *      describes an EventAck message looking like.
854
 */
855
 
856
int i2o_event_ack(struct i2o_controller *c, u32 *msg)
857
{
858
        struct i2o_message *m = (struct i2o_message *)msg;
859
 
860
        m->function = I2O_CMD_UTIL_EVT_ACK;
861
 
862
        return i2o_post_wait(c, msg, m->size * 4, 2);
863
}
864
 
865
/*
866
 * Core event handler.  Runs as a separate thread and is woken
867
 * up whenever there is an Executive class event.
868
 */
869
static int i2o_core_evt(void *reply_data)
870
{
871
        struct reply_info *reply = (struct reply_info *) reply_data;
872
        u32 *msg = reply->msg;
873
        struct i2o_controller *c = NULL;
874
        unsigned long flags;
875
 
876
        lock_kernel();
877
        daemonize();
878
        unlock_kernel();
879
 
880
        strcpy(current->comm, "i2oevtd");
881
        evt_running = 1;
882
 
883
        while(1)
884
        {
885
                if(down_interruptible(&evt_sem))
886
                {
887
                        dprintk(KERN_INFO "I2O event thread dead\n");
888
                        printk("exiting...");
889
                        evt_running = 0;
890
                        complete_and_exit(&evt_dead, 0);
891
                }
892
 
893
                /*
894
                 * Copy the data out of the queue so that we don't have to lock
895
                 * around the whole function and just around the qlen update
896
                 */
897
                spin_lock_irqsave(&i2o_evt_lock, flags);
898
                memcpy(reply, &events[evt_out], sizeof(struct reply_info));
899
                MODINC(evt_out, I2O_EVT_Q_LEN);
900
                evt_q_len--;
901
                spin_unlock_irqrestore(&i2o_evt_lock, flags);
902
 
903
                c = reply->iop;
904
                dprintk(KERN_INFO "I2O IRTOS EVENT: iop%d, event %#10x\n", c->unit, msg[4]);
905
 
906
                /*
907
                 * We do not attempt to delete/quiesce/etc. the controller if
908
                 * some sort of error indidication occurs.  We may want to do
909
                 * so in the future, but for now we just let the user deal with
910
                 * it.  One reason for this is that what to do with an error
911
                 * or when to send what ærror is not really agreed on, so
912
                 * we get errors that may not be fatal but just look like they
913
                 * are...so let the user deal with it.
914
                 */
915
                switch(msg[4])
916
                {
917
                        case I2O_EVT_IND_EXEC_RESOURCE_LIMITS:
918
                                printk(KERN_ERR "%s: Out of resources\n", c->name);
919
                                break;
920
 
921
                        case I2O_EVT_IND_EXEC_POWER_FAIL:
922
                                printk(KERN_ERR "%s: Power failure\n", c->name);
923
                                break;
924
 
925
                        case I2O_EVT_IND_EXEC_HW_FAIL:
926
                        {
927
                                char *fail[] =
928
                                        {
929
                                                "Unknown Error",
930
                                                "Power Lost",
931
                                                "Code Violation",
932
                                                "Parity Error",
933
                                                "Code Execution Exception",
934
                                                "Watchdog Timer Expired"
935
                                        };
936
 
937
                                if(msg[5] <= 6)
938
                                        printk(KERN_ERR "%s: Hardware Failure: %s\n",
939
                                                c->name, fail[msg[5]]);
940
                                else
941
                                        printk(KERN_ERR "%s: Unknown Hardware Failure\n", c->name);
942
 
943
                                break;
944
                        }
945
 
946
                        /*
947
                         * New device created
948
                         * - Create a new i2o_device entry
949
                         * - Inform all interested drivers about this device's existence
950
                         */
951
                        case I2O_EVT_IND_EXEC_NEW_LCT_ENTRY:
952
                        {
953
                                struct i2o_device *d = (struct i2o_device *)
954
                                        kmalloc(sizeof(struct i2o_device), GFP_KERNEL);
955
                                int i;
956
 
957
                                if (d == NULL) {
958
                                        printk(KERN_EMERG "i2oevtd: out of memory\n");
959
                                        break;
960
                                }
961
                                memcpy(&d->lct_data, &msg[5], sizeof(i2o_lct_entry));
962
 
963
                                d->next = NULL;
964
                                d->controller = c;
965
                                d->flags = 0;
966
 
967
                                i2o_report_controller_unit(c, d);
968
                                i2o_install_device(c,d);
969
 
970
                                for(i = 0; i < MAX_I2O_MODULES; i++)
971
                                {
972
                                        if(i2o_handlers[i] &&
973
                                                i2o_handlers[i]->new_dev_notify &&
974
                                                (i2o_handlers[i]->class&d->lct_data.class_id))
975
                                                {
976
                                                spin_lock(&i2o_dev_lock);
977
                                                i2o_handlers[i]->new_dev_notify(c,d);
978
                                                spin_unlock(&i2o_dev_lock);
979
                                                }
980
                                }
981
 
982
                                break;
983
                        }
984
 
985
                        /*
986
                         * LCT entry for a device has been modified, so update it
987
                         * internally.
988
                         */
989
                        case I2O_EVT_IND_EXEC_MODIFIED_LCT:
990
                        {
991
                                struct i2o_device *d;
992
                                i2o_lct_entry *new_lct = (i2o_lct_entry *)&msg[5];
993
 
994
                                for(d = c->devices; d; d = d->next)
995
                                {
996
                                        if(d->lct_data.tid == new_lct->tid)
997
                                        {
998
                                                memcpy(&d->lct_data, new_lct, sizeof(i2o_lct_entry));
999
                                                break;
1000
                                        }
1001
                                }
1002
                                break;
1003
                        }
1004
 
1005
                        case I2O_EVT_IND_CONFIGURATION_FLAG:
1006
                                printk(KERN_WARNING "%s requires user configuration\n", c->name);
1007
                                break;
1008
 
1009
                        case I2O_EVT_IND_GENERAL_WARNING:
1010
                                printk(KERN_WARNING "%s: Warning notification received!"
1011
                                        "Check configuration for errors!\n", c->name);
1012
                                break;
1013
 
1014
                        case I2O_EVT_IND_EVT_MASK_MODIFIED:
1015
                                /* Well I guess that was us hey .. */
1016
                                break;
1017
 
1018
                        default:
1019
                                printk(KERN_WARNING "%s: No handler for event (0x%08x)\n", c->name, msg[4]);
1020
                                break;
1021
                }
1022
        }
1023
 
1024
        return 0;
1025
}
1026
 
1027
/*
1028
 * Dynamic LCT update.  This compares the LCT with the currently
1029
 * installed devices to check for device deletions..this needed b/c there
1030
 * is no DELETED_LCT_ENTRY EventIndicator for the Executive class so
1031
 * we can't just have the event handler do this...annoying
1032
 *
1033
 * This is a hole in the spec that will hopefully be fixed someday.
1034
 */
1035
static int i2o_dyn_lct(void *foo)
1036
{
1037
        struct i2o_controller *c = (struct i2o_controller *)foo;
1038
        struct i2o_device *d = NULL;
1039
        struct i2o_device *d1 = NULL;
1040
        int i = 0;
1041
        int found = 0;
1042
        int entries;
1043
        void *tmp;
1044
        char name[16];
1045
 
1046
        lock_kernel();
1047
        daemonize();
1048
        unlock_kernel();
1049
 
1050
        sprintf(name, "iop%d_lctd", c->unit);
1051
        strcpy(current->comm, name);
1052
 
1053
        c->lct_running = 1;
1054
 
1055
        while(1)
1056
        {
1057
                down_interruptible(&c->lct_sem);
1058
                if(signal_pending(current))
1059
                {
1060
                        dprintk(KERN_ERR "%s: LCT thread dead\n", c->name);
1061
                        c->lct_running = 0;
1062
                        return 0;
1063
                }
1064
 
1065
                entries = c->dlct->table_size;
1066
                entries -= 3;
1067
                entries /= 9;
1068
 
1069
                dprintk(KERN_INFO "%s: Dynamic LCT Update\n",c->name);
1070
                dprintk(KERN_INFO "%s: Dynamic LCT contains %d entries\n", c->name, entries);
1071
 
1072
                if(!entries)
1073
                {
1074
                        printk(KERN_INFO "%s: Empty LCT???\n", c->name);
1075
                        continue;
1076
                }
1077
 
1078
                /*
1079
                 * Loop through all the devices on the IOP looking for their
1080
                 * LCT data in the LCT.  We assume that TIDs are not repeated.
1081
                 * as that is the only way to really tell.  It's been confirmed
1082
                 * by the IRTOS vendor(s?) that TIDs are not reused until they
1083
                 * wrap arround(4096), and I doubt a system will up long enough
1084
                 * to create/delete that many devices.
1085
                 */
1086
                for(d = c->devices; d; )
1087
                {
1088
                        found = 0;
1089
                        d1 = d->next;
1090
 
1091
                        for(i = 0; i < entries; i++)
1092
                        {
1093
                                if(d->lct_data.tid == c->dlct->lct_entry[i].tid)
1094
                                {
1095
                                        found = 1;
1096
                                        break;
1097
                                }
1098
                        }
1099
                        if(!found)
1100
                        {
1101
                                dprintk(KERN_INFO "i2o_core: Deleted device!\n");
1102
                                spin_lock(&i2o_dev_lock);
1103
                                i2o_delete_device(d);
1104
                                spin_unlock(&i2o_dev_lock);
1105
                        }
1106
                        d = d1;
1107
                }
1108
 
1109
                /*
1110
                 * Tell LCT to renotify us next time there is a change
1111
                 */
1112
                i2o_lct_notify(c);
1113
 
1114
                /*
1115
                 * Copy new LCT into public LCT
1116
                 *
1117
                 * Possible race if someone is reading LCT while  we are copying
1118
                 * over it. If this happens, we'll fix it then. but I doubt that
1119
                 * the LCT will get updated often enough or will get read by
1120
                 * a user often enough to worry.
1121
                 */
1122
                if(c->lct->table_size < c->dlct->table_size)
1123
                {
1124
                        tmp = c->lct;
1125
                        c->lct = kmalloc(c->dlct->table_size<<2, GFP_KERNEL);
1126
                        if(!c->lct)
1127
                        {
1128
                                printk(KERN_ERR "%s: No memory for LCT!\n", c->name);
1129
                                c->lct = tmp;
1130
                                continue;
1131
                        }
1132
                        kfree(tmp);
1133
                }
1134
                memcpy(c->lct, c->dlct, c->dlct->table_size<<2);
1135
        }
1136
 
1137
        return 0;
1138
}
1139
 
1140
/**
1141
 *      i2o_run_queue   -       process pending events on a controller
1142
 *      @c: controller to process
1143
 *
1144
 *      This is called by the bus specific driver layer when an interrupt
1145
 *      or poll of this card interface is desired.
1146
 */
1147
 
1148
void i2o_run_queue(struct i2o_controller *c)
1149
{
1150
        struct i2o_message *m;
1151
        u32 mv;
1152
        u32 *msg;
1153
 
1154
        /*
1155
         * Old 960 steppings had a bug in the I2O unit that caused
1156
         * the queue to appear empty when it wasn't.
1157
         */
1158
        if((mv=I2O_REPLY_READ32(c))==0xFFFFFFFF)
1159
                mv=I2O_REPLY_READ32(c);
1160
 
1161
        while(mv!=0xFFFFFFFF)
1162
        {
1163
                struct i2o_handler *i;
1164
                /* Map the message from the page frame map to kernel virtual */
1165
                /* m=(struct i2o_message *)(mv - (unsigned long)c->page_frame_map + (unsigned long)c->page_frame); */
1166
                m=(struct i2o_message *)bus_to_virt(mv);
1167
                msg=(u32*)m;
1168
 
1169
                /*
1170
                 *      Ensure this message is seen coherently but cachably by
1171
                 *      the processor
1172
                 */
1173
 
1174
                pci_dma_sync_single(c->pdev, c->page_frame_map, MSG_FRAME_SIZE, PCI_DMA_FROMDEVICE);
1175
 
1176
                /*
1177
                 *      Despatch it
1178
                 */
1179
 
1180
                i=i2o_handlers[m->initiator_context&(MAX_I2O_MODULES-1)];
1181
                if(i && i->reply)
1182
                        i->reply(i,c,m);
1183
                else
1184
                {
1185
                        printk(KERN_WARNING "I2O: Spurious reply to handler %d\n",
1186
                                m->initiator_context&(MAX_I2O_MODULES-1));
1187
                }
1188
                i2o_flush_reply(c,mv);
1189
                mb();
1190
 
1191
                /* That 960 bug again... */
1192
                if((mv=I2O_REPLY_READ32(c))==0xFFFFFFFF)
1193
                        mv=I2O_REPLY_READ32(c);
1194
        }
1195
}
1196
 
1197
 
1198
/**
1199
 *      i2o_get_class_name -    do i2o class name lookup
1200
 *      @class: class number
1201
 *
1202
 *      Return a descriptive string for an i2o class
1203
 */
1204
 
1205
const char *i2o_get_class_name(int class)
1206
{
1207
        int idx = 16;
1208
        static char *i2o_class_name[] = {
1209
                "Executive",
1210
                "Device Driver Module",
1211
                "Block Device",
1212
                "Tape Device",
1213
                "LAN Interface",
1214
                "WAN Interface",
1215
                "Fibre Channel Port",
1216
                "Fibre Channel Device",
1217
                "SCSI Device",
1218
                "ATE Port",
1219
                "ATE Device",
1220
                "Floppy Controller",
1221
                "Floppy Device",
1222
                "Secondary Bus Port",
1223
                "Peer Transport Agent",
1224
                "Peer Transport",
1225
                "Unknown"
1226
        };
1227
 
1228
        switch(class&0xFFF)
1229
        {
1230
                case I2O_CLASS_EXECUTIVE:
1231
                        idx = 0; break;
1232
                case I2O_CLASS_DDM:
1233
                        idx = 1; break;
1234
                case I2O_CLASS_RANDOM_BLOCK_STORAGE:
1235
                        idx = 2; break;
1236
                case I2O_CLASS_SEQUENTIAL_STORAGE:
1237
                        idx = 3; break;
1238
                case I2O_CLASS_LAN:
1239
                        idx = 4; break;
1240
                case I2O_CLASS_WAN:
1241
                        idx = 5; break;
1242
                case I2O_CLASS_FIBRE_CHANNEL_PORT:
1243
                        idx = 6; break;
1244
                case I2O_CLASS_FIBRE_CHANNEL_PERIPHERAL:
1245
                        idx = 7; break;
1246
                case I2O_CLASS_SCSI_PERIPHERAL:
1247
                        idx = 8; break;
1248
                case I2O_CLASS_ATE_PORT:
1249
                        idx = 9; break;
1250
                case I2O_CLASS_ATE_PERIPHERAL:
1251
                        idx = 10; break;
1252
                case I2O_CLASS_FLOPPY_CONTROLLER:
1253
                        idx = 11; break;
1254
                case I2O_CLASS_FLOPPY_DEVICE:
1255
                        idx = 12; break;
1256
                case I2O_CLASS_BUS_ADAPTER_PORT:
1257
                        idx = 13; break;
1258
                case I2O_CLASS_PEER_TRANSPORT_AGENT:
1259
                        idx = 14; break;
1260
                case I2O_CLASS_PEER_TRANSPORT:
1261
                        idx = 15; break;
1262
        }
1263
 
1264
        return i2o_class_name[idx];
1265
}
1266
 
1267
 
1268
/**
1269
 *      i2o_wait_message        -       obtain an i2o message from the IOP
1270
 *      @c: controller
1271
 *      @why: explanation
1272
 *
1273
 *      This function waits up to 5 seconds for a message slot to be
1274
 *      available. If no message is available it prints an error message
1275
 *      that is expected to be what the message will be used for (eg
1276
 *      "get_status"). 0xFFFFFFFF is returned on a failure.
1277
 *
1278
 *      On a success the message is returned. This is the physical page
1279
 *      frame offset address from the read port. (See the i2o spec)
1280
 */
1281
 
1282
u32 i2o_wait_message(struct i2o_controller *c, char *why)
1283
{
1284
        long time=jiffies;
1285
        u32 m;
1286
        while((m=I2O_POST_READ32(c))==0xFFFFFFFF)
1287
        {
1288
                if((jiffies-time)>=5*HZ)
1289
                {
1290
                        dprintk(KERN_ERR "%s: Timeout waiting for message frame to send %s.\n",
1291
                                c->name, why);
1292
                        return 0xFFFFFFFF;
1293
                }
1294
                schedule();
1295
                barrier();
1296
        }
1297
        return m;
1298
}
1299
 
1300
/**
1301
 *      i2o_report_controller_unit - print information about a tid
1302
 *      @c: controller
1303
 *      @d: device
1304
 *
1305
 *      Dump an information block associated with a given unit (TID). The
1306
 *      tables are read and a block of text is output to printk that is
1307
 *      formatted intended for the user.
1308
 */
1309
 
1310
void i2o_report_controller_unit(struct i2o_controller *c, struct i2o_device *d)
1311
{
1312
        char buf[64];
1313
        char str[22];
1314
        int ret;
1315
        int unit = d->lct_data.tid;
1316
 
1317
        if(verbose==0)
1318
                return;
1319
 
1320
        printk(KERN_INFO "Target ID %d.\n", unit);
1321
        if((ret=i2o_query_scalar(c, unit, 0xF100, 3, buf, 16))>=0)
1322
        {
1323
                buf[16]=0;
1324
                printk(KERN_INFO "     Vendor: %s\n", buf);
1325
        }
1326
        if((ret=i2o_query_scalar(c, unit, 0xF100, 4, buf, 16))>=0)
1327
        {
1328
                buf[16]=0;
1329
                printk(KERN_INFO "     Device: %s\n", buf);
1330
        }
1331
        if(i2o_query_scalar(c, unit, 0xF100, 5, buf, 16)>=0)
1332
        {
1333
                buf[16]=0;
1334
                printk(KERN_INFO "     Description: %s\n", buf);
1335
        }
1336
        if((ret=i2o_query_scalar(c, unit, 0xF100, 6, buf, 8))>=0)
1337
        {
1338
                buf[8]=0;
1339
                printk(KERN_INFO "        Rev: %s\n", buf);
1340
        }
1341
 
1342
        printk(KERN_INFO "    Class: ");
1343
        sprintf(str, "%-21s", i2o_get_class_name(d->lct_data.class_id));
1344
        printk("%s\n", str);
1345
 
1346
        printk(KERN_INFO "  Subclass: 0x%04X\n", d->lct_data.sub_class);
1347
        printk(KERN_INFO "     Flags: ");
1348
 
1349
        if(d->lct_data.device_flags&(1<<0))
1350
                printk("C");            // ConfigDialog requested
1351
        if(d->lct_data.device_flags&(1<<1))
1352
                printk("U");            // Multi-user capable
1353
        if(!(d->lct_data.device_flags&(1<<4)))
1354
                printk("P");            // Peer service enabled!
1355
        if(!(d->lct_data.device_flags&(1<<5)))
1356
                printk("M");            // Mgmt service enabled!
1357
        printk("\n");
1358
 
1359
}
1360
 
1361
 
1362
/*
1363
 *      Parse the hardware resource table. Right now we print it out
1364
 *      and don't do a lot with it. We should collate these and then
1365
 *      interact with the Linux resource allocation block.
1366
 *
1367
 *      Lets prove we can read it first eh ?
1368
 *
1369
 *      This is full of endianisms!
1370
 */
1371
 
1372
static int i2o_parse_hrt(struct i2o_controller *c)
1373
{
1374
#ifdef DRIVERDEBUG
1375
        u32 *rows=(u32*)c->hrt;
1376
        u8 *p=(u8 *)c->hrt;
1377
        u8 *d;
1378
        int count;
1379
        int length;
1380
        int i;
1381
        int state;
1382
 
1383
        if(p[3]!=0)
1384
        {
1385
                printk(KERN_ERR "%s: HRT table for controller is too new a version.\n",
1386
                        c->name);
1387
                return -1;
1388
        }
1389
 
1390
        count=p[0]|(p[1]<<8);
1391
        length = p[2];
1392
 
1393
        printk(KERN_INFO "%s: HRT has %d entries of %d bytes each.\n",
1394
                c->name, count, length<<2);
1395
 
1396
        rows+=2;
1397
 
1398
        for(i=0;i<count;i++)
1399
        {
1400
                printk(KERN_INFO "Adapter %08X: ", rows[0]);
1401
                p=(u8 *)(rows+1);
1402
                d=(u8 *)(rows+2);
1403
                state=p[1]<<8|p[0];
1404
 
1405
                printk("TID %04X:[", state&0xFFF);
1406
                state>>=12;
1407
                if(state&(1<<0))
1408
                        printk("H");            /* Hidden */
1409
                if(state&(1<<2))
1410
                {
1411
                        printk("P");            /* Present */
1412
                        if(state&(1<<1))
1413
                                printk("C");    /* Controlled */
1414
                }
1415
                if(state>9)
1416
                        printk("*");            /* Hard */
1417
 
1418
                printk("]:");
1419
 
1420
                switch(p[3]&0xFFFF)
1421
                {
1422
                        case 0:
1423
                                /* Adapter private bus - easy */
1424
                                printk("Local bus %d: I/O at 0x%04X Mem 0x%08X",
1425
                                        p[2], d[1]<<8|d[0], *(u32 *)(d+4));
1426
                                break;
1427
                        case 1:
1428
                                /* ISA bus */
1429
                                printk("ISA %d: CSN %d I/O at 0x%04X Mem 0x%08X",
1430
                                        p[2], d[2], d[1]<<8|d[0], *(u32 *)(d+4));
1431
                                break;
1432
 
1433
                        case 2: /* EISA bus */
1434
                                printk("EISA %d: Slot %d I/O at 0x%04X Mem 0x%08X",
1435
                                        p[2], d[3], d[1]<<8|d[0], *(u32 *)(d+4));
1436
                                break;
1437
 
1438
                        case 3: /* MCA bus */
1439
                                printk("MCA %d: Slot %d I/O at 0x%04X Mem 0x%08X",
1440
                                        p[2], d[3], d[1]<<8|d[0], *(u32 *)(d+4));
1441
                                break;
1442
 
1443
                        case 4: /* PCI bus */
1444
                                printk("PCI %d: Bus %d Device %d Function %d",
1445
                                        p[2], d[2], d[1], d[0]);
1446
                                break;
1447
 
1448
                        case 0x80: /* Other */
1449
                        default:
1450
                                printk("Unsupported bus type.");
1451
                                break;
1452
                }
1453
                printk("\n");
1454
                rows+=length;
1455
        }
1456
#endif
1457
        return 0;
1458
}
1459
 
1460
/*
1461
 *      The logical configuration table tells us what we can talk to
1462
 *      on the board. Most of the stuff isn't interesting to us.
1463
 */
1464
 
1465
static int i2o_parse_lct(struct i2o_controller *c)
1466
{
1467
        int i;
1468
        int max;
1469
        int tid;
1470
        struct i2o_device *d;
1471
        i2o_lct *lct = c->lct;
1472
 
1473
        if (lct == NULL) {
1474
                printk(KERN_ERR "%s: LCT is empty???\n", c->name);
1475
                return -1;
1476
        }
1477
 
1478
        max = lct->table_size;
1479
        max -= 3;
1480
        max /= 9;
1481
 
1482
        printk(KERN_INFO "%s: LCT has %d entries.\n", c->name, max);
1483
 
1484
        if(lct->iop_flags&(1<<0))
1485
                printk(KERN_WARNING "%s: Configuration dialog desired.\n", c->name);
1486
 
1487
        for(i=0;i<max;i++)
1488
        {
1489
                d = (struct i2o_device *)kmalloc(sizeof(struct i2o_device), GFP_KERNEL);
1490
                if(d==NULL)
1491
                {
1492
                        printk(KERN_CRIT "i2o_core: Out of memory for I2O device data.\n");
1493
                        return -ENOMEM;
1494
                }
1495
 
1496
                d->controller = c;
1497
                d->next = NULL;
1498
 
1499
                memcpy(&d->lct_data, &lct->lct_entry[i], sizeof(i2o_lct_entry));
1500
 
1501
                d->flags = 0;
1502
                tid = d->lct_data.tid;
1503
 
1504
                i2o_report_controller_unit(c, d);
1505
 
1506
                i2o_install_device(c, d);
1507
        }
1508
        return 0;
1509
}
1510
 
1511
 
1512
/**
1513
 *      i2o_quiesce_controller - quiesce controller
1514
 *      @c: controller
1515
 *
1516
 *      Quiesce an IOP. Causes IOP to make external operation quiescent
1517
 *      (i2o 'READY' state). Internal operation of the IOP continues normally.
1518
 */
1519
 
1520
int i2o_quiesce_controller(struct i2o_controller *c)
1521
{
1522
        u32 msg[4];
1523
        int ret;
1524
 
1525
        i2o_status_get(c);
1526
 
1527
        /* SysQuiesce discarded if IOP not in READY or OPERATIONAL state */
1528
 
1529
        if ((c->status_block->iop_state != ADAPTER_STATE_READY) &&
1530
                (c->status_block->iop_state != ADAPTER_STATE_OPERATIONAL))
1531
        {
1532
                return 0;
1533
        }
1534
 
1535
        msg[0] = FOUR_WORD_MSG_SIZE|SGL_OFFSET_0;
1536
        msg[1] = I2O_CMD_SYS_QUIESCE<<24|HOST_TID<<12|ADAPTER_TID;
1537
        msg[3] = 0;
1538
 
1539
        /* Long timeout needed for quiesce if lots of devices */
1540
 
1541
        if ((ret = i2o_post_wait(c, msg, sizeof(msg), 240)))
1542
                printk(KERN_INFO "%s: Unable to quiesce (status=%#x).\n",
1543
                        c->name, -ret);
1544
        else
1545
                dprintk(KERN_INFO "%s: Quiesced.\n", c->name);
1546
 
1547
        i2o_status_get(c); // Entered READY state
1548
        return ret;
1549
}
1550
 
1551
/**
1552
 *      i2o_enable_controller - move controller from ready to operational
1553
 *      @c: controller
1554
 *
1555
 *      Enable IOP. This allows the IOP to resume external operations and
1556
 *      reverses the effect of a quiesce. In the event of an error a negative
1557
 *      errno code is returned.
1558
 */
1559
 
1560
int i2o_enable_controller(struct i2o_controller *c)
1561
{
1562
        u32 msg[4];
1563
        int ret;
1564
 
1565
        i2o_status_get(c);
1566
 
1567
        /* Enable only allowed on READY state */
1568
        if(c->status_block->iop_state != ADAPTER_STATE_READY)
1569
                return -EINVAL;
1570
 
1571
        msg[0]=FOUR_WORD_MSG_SIZE|SGL_OFFSET_0;
1572
        msg[1]=I2O_CMD_SYS_ENABLE<<24|HOST_TID<<12|ADAPTER_TID;
1573
 
1574
        /* How long of a timeout do we need? */
1575
 
1576
        if ((ret = i2o_post_wait(c, msg, sizeof(msg), 240)))
1577
                printk(KERN_ERR "%s: Could not enable (status=%#x).\n",
1578
                        c->name, -ret);
1579
        else
1580
                dprintk(KERN_INFO "%s: Enabled.\n", c->name);
1581
 
1582
        i2o_status_get(c); // entered OPERATIONAL state
1583
 
1584
        return ret;
1585
}
1586
 
1587
/**
1588
 *      i2o_clear_controller    -       clear a controller
1589
 *      @c: controller
1590
 *
1591
 *      Clear an IOP to HOLD state, ie. terminate external operations, clear all
1592
 *      input queues and prepare for a system restart. IOP's internal operation
1593
 *      continues normally and the outbound queue is alive.
1594
 *      The IOP is not expected to rebuild its LCT.
1595
 */
1596
 
1597
int i2o_clear_controller(struct i2o_controller *c)
1598
{
1599
        struct i2o_controller *iop;
1600
        u32 msg[4];
1601
        int ret;
1602
 
1603
        /* Quiesce all IOPs first */
1604
 
1605
        for (iop = i2o_controller_chain; iop; iop = iop->next)
1606
                i2o_quiesce_controller(iop);
1607
 
1608
        msg[0]=FOUR_WORD_MSG_SIZE|SGL_OFFSET_0;
1609
        msg[1]=I2O_CMD_ADAPTER_CLEAR<<24|HOST_TID<<12|ADAPTER_TID;
1610
        msg[3]=0;
1611
 
1612
        if ((ret=i2o_post_wait(c, msg, sizeof(msg), 30)))
1613
                printk(KERN_INFO "%s: Unable to clear (status=%#x).\n",
1614
                        c->name, -ret);
1615
        else
1616
                dprintk(KERN_INFO "%s: Cleared.\n",c->name);
1617
 
1618
        i2o_status_get(c);
1619
 
1620
        /* Enable other IOPs */
1621
 
1622
        for (iop = i2o_controller_chain; iop; iop = iop->next)
1623
                if (iop != c)
1624
                        i2o_enable_controller(iop);
1625
 
1626
        return ret;
1627
}
1628
 
1629
 
1630
/**
1631
 *      i2o_reset_controller    -       reset an IOP
1632
 *      @c: controller to reset
1633
 *
1634
 *      Reset the IOP into INIT state and wait until IOP gets into RESET state.
1635
 *      Terminate all external operations, clear IOP's inbound and outbound
1636
 *      queues, terminate all DDMs, and reload the IOP's operating environment
1637
 *      and all local DDMs. The IOP rebuilds its LCT.
1638
 */
1639
 
1640
static int i2o_reset_controller(struct i2o_controller *c)
1641
{
1642
        struct i2o_controller *iop;
1643
        u32 m;
1644
        u8 *status;
1645
        u32 *msg;
1646
        long time;
1647
 
1648
        /* Quiesce all IOPs first */
1649
 
1650
        for (iop = i2o_controller_chain; iop; iop = iop->next)
1651
        {
1652
                if(iop->type != I2O_TYPE_PCI || !iop->bus.pci.dpt)
1653
                        i2o_quiesce_controller(iop);
1654
        }
1655
 
1656
        m=i2o_wait_message(c, "AdapterReset");
1657
        if(m==0xFFFFFFFF)
1658
                return -ETIMEDOUT;
1659
        msg=(u32 *)(c->mem_offset+m);
1660
 
1661
        status=(void *)kmalloc(4, GFP_KERNEL);
1662
        if(status==NULL) {
1663
                printk(KERN_ERR "IOP reset failed - no free memory.\n");
1664
                return -ENOMEM;
1665
        }
1666
        memset(status, 0, 4);
1667
 
1668
        msg[0]=EIGHT_WORD_MSG_SIZE|SGL_OFFSET_0;
1669
        msg[1]=I2O_CMD_ADAPTER_RESET<<24|HOST_TID<<12|ADAPTER_TID;
1670
        msg[2]=core_context;
1671
        msg[3]=0;
1672
        msg[4]=0;
1673
        msg[5]=0;
1674
        msg[6]=virt_to_bus(status);
1675
        msg[7]=0;        /* 64bit host FIXME */
1676
 
1677
        i2o_post_message(c,m);
1678
 
1679
        /* Wait for a reply */
1680
        time=jiffies;
1681
        while(*status==0)
1682
        {
1683
                if((jiffies-time)>=20*HZ)
1684
                {
1685
                        printk(KERN_ERR "IOP reset timeout.\n");
1686
                        // Better to leak this for safety: kfree(status);
1687
                        return -ETIMEDOUT;
1688
                }
1689
                schedule();
1690
                barrier();
1691
        }
1692
 
1693
        if (*status==I2O_CMD_IN_PROGRESS)
1694
        {
1695
                /*
1696
                 * Once the reset is sent, the IOP goes into the INIT state
1697
                 * which is indeterminate.  We need to wait until the IOP
1698
                 * has rebooted before we can let the system talk to
1699
                 * it. We read the inbound Free_List until a message is
1700
                 * available.  If we can't read one in the given ammount of
1701
                 * time, we assume the IOP could not reboot properly.
1702
                 */
1703
 
1704
                dprintk(KERN_INFO "%s: Reset in progress, waiting for reboot...\n",
1705
                        c->name);
1706
 
1707
                time = jiffies;
1708
                m = I2O_POST_READ32(c);
1709
                while(m == 0XFFFFFFFF)
1710
                {
1711
                        if((jiffies-time) >= 30*HZ)
1712
                        {
1713
                                printk(KERN_ERR "%s: Timeout waiting for IOP reset.\n",
1714
                                                c->name);
1715
                                return -ETIMEDOUT;
1716
                        }
1717
                        schedule();
1718
                        barrier();
1719
                        m = I2O_POST_READ32(c);
1720
                }
1721
                i2o_flush_reply(c,m);
1722
        }
1723
 
1724
        /* If IopReset was rejected or didn't perform reset, try IopClear */
1725
 
1726
        i2o_status_get(c);
1727
        if (status[0] == I2O_CMD_REJECTED ||
1728
                c->status_block->iop_state != ADAPTER_STATE_RESET)
1729
        {
1730
                printk(KERN_WARNING "%s: Reset rejected, trying to clear\n",c->name);
1731
                i2o_clear_controller(c);
1732
        }
1733
        else
1734
                dprintk(KERN_INFO "%s: Reset completed.\n", c->name);
1735
 
1736
        /* Enable other IOPs */
1737
 
1738
        for (iop = i2o_controller_chain; iop; iop = iop->next)
1739
                if (iop != c)
1740
                        i2o_enable_controller(iop);
1741
 
1742
        kfree(status);
1743
        return 0;
1744
}
1745
 
1746
 
1747
/**
1748
 *      i2o_status_get  -       get the status block for the IOP
1749
 *      @c: controller
1750
 *
1751
 *      Issue a status query on the controller. This updates the
1752
 *      attached status_block. If the controller fails to reply or an
1753
 *      error occurs then a negative errno code is returned. On success
1754
 *      zero is returned and the status_blok is updated.
1755
 */
1756
 
1757
int i2o_status_get(struct i2o_controller *c)
1758
{
1759
        long time;
1760
        u32 m;
1761
        u32 *msg;
1762
        u8 *status_block;
1763
 
1764
        if (c->status_block == NULL)
1765
        {
1766
                c->status_block = (i2o_status_block *)
1767
                        kmalloc(sizeof(i2o_status_block),GFP_KERNEL);
1768
                if (c->status_block == NULL)
1769
                {
1770
                        printk(KERN_CRIT "%s: Get Status Block failed; Out of memory.\n",
1771
                                c->name);
1772
                        return -ENOMEM;
1773
                }
1774
        }
1775
 
1776
        status_block = (u8*)c->status_block;
1777
        memset(c->status_block,0,sizeof(i2o_status_block));
1778
 
1779
        m=i2o_wait_message(c, "StatusGet");
1780
        if(m==0xFFFFFFFF)
1781
                return -ETIMEDOUT;
1782
        msg=(u32 *)(c->mem_offset+m);
1783
 
1784
        msg[0]=NINE_WORD_MSG_SIZE|SGL_OFFSET_0;
1785
        msg[1]=I2O_CMD_STATUS_GET<<24|HOST_TID<<12|ADAPTER_TID;
1786
        msg[2]=core_context;
1787
        msg[3]=0;
1788
        msg[4]=0;
1789
        msg[5]=0;
1790
        msg[6]=virt_to_bus(c->status_block);
1791
        msg[7]=0;   /* 64bit host FIXME */
1792
        msg[8]=sizeof(i2o_status_block); /* always 88 bytes */
1793
 
1794
        i2o_post_message(c,m);
1795
 
1796
        /* Wait for a reply */
1797
 
1798
        time=jiffies;
1799
        while(status_block[87]!=0xFF)
1800
        {
1801
                if((jiffies-time)>=5*HZ)
1802
                {
1803
                        printk(KERN_ERR "%s: Get status timeout.\n",c->name);
1804
                        return -ETIMEDOUT;
1805
                }
1806
                schedule();
1807
                barrier();
1808
        }
1809
 
1810
#ifdef DRIVERDEBUG
1811
        printk(KERN_INFO "%s: State = ", c->name);
1812
        switch (c->status_block->iop_state) {
1813
                case 0x01:
1814
                        printk("INIT\n");
1815
                        break;
1816
                case 0x02:
1817
                        printk("RESET\n");
1818
                        break;
1819
                case 0x04:
1820
                        printk("HOLD\n");
1821
                        break;
1822
                case 0x05:
1823
                        printk("READY\n");
1824
                        break;
1825
                case 0x08:
1826
                        printk("OPERATIONAL\n");
1827
                        break;
1828
                case 0x10:
1829
                        printk("FAILED\n");
1830
                        break;
1831
                case 0x11:
1832
                        printk("FAULTED\n");
1833
                        break;
1834
                default:
1835
                        printk("%x (unknown !!)\n",c->status_block->iop_state);
1836
}
1837
#endif   
1838
 
1839
        return 0;
1840
}
1841
 
1842
/*
1843
 * Get the Hardware Resource Table for the device.
1844
 * The HRT contains information about possible hidden devices
1845
 * but is mostly useless to us
1846
 */
1847
int i2o_hrt_get(struct i2o_controller *c)
1848
{
1849
        u32 msg[6];
1850
        int ret, size = sizeof(i2o_hrt);
1851
 
1852
        /* First read just the header to figure out the real size */
1853
 
1854
        do  {
1855
                if (c->hrt == NULL) {
1856
                        c->hrt=kmalloc(size, GFP_KERNEL);
1857
                        if (c->hrt == NULL) {
1858
                                printk(KERN_CRIT "%s: Hrt Get failed; Out of memory.\n", c->name);
1859
                                return -ENOMEM;
1860
                        }
1861
                }
1862
 
1863
                msg[0]= SIX_WORD_MSG_SIZE| SGL_OFFSET_4;
1864
                msg[1]= I2O_CMD_HRT_GET<<24 | HOST_TID<<12 | ADAPTER_TID;
1865
                msg[3]= 0;
1866
                msg[4]= (0xD0000000 | size);    /* Simple transaction */
1867
                msg[5]= virt_to_bus(c->hrt);    /* Dump it here */
1868
 
1869
                ret = i2o_post_wait_mem(c, msg, sizeof(msg), 20, c->hrt, NULL);
1870
 
1871
                if(ret == -ETIMEDOUT)
1872
                {
1873
                        /* The HRT block we used is in limbo somewhere. When the iop wakes up
1874
                           we will recover it */
1875
                        c->hrt = NULL;
1876
                        return ret;
1877
                }
1878
 
1879
                if(ret<0)
1880
                {
1881
                        printk(KERN_ERR "%s: Unable to get HRT (status=%#x)\n",
1882
                                c->name, -ret);
1883
                        return ret;
1884
                }
1885
 
1886
                if (c->hrt->num_entries * c->hrt->entry_len << 2 > size) {
1887
                        size = c->hrt->num_entries * c->hrt->entry_len << 2;
1888
                        kfree(c->hrt);
1889
                        c->hrt = NULL;
1890
                }
1891
        } while (c->hrt == NULL);
1892
 
1893
        i2o_parse_hrt(c); // just for debugging
1894
 
1895
        return 0;
1896
}
1897
 
1898
/*
1899
 * Send the I2O System Table to the specified IOP
1900
 *
1901
 * The system table contains information about all the IOPs in the
1902
 * system.  It is build and then sent to each IOP so that IOPs can
1903
 * establish connections between each other.
1904
 *
1905
 */
1906
static int i2o_systab_send(struct i2o_controller *iop)
1907
{
1908
        u32 msg[12];
1909
        int ret;
1910
        u32 *privbuf = kmalloc(16, GFP_KERNEL);
1911
        if(privbuf == NULL)
1912
                return -ENOMEM;
1913
 
1914
        if(iop->type == I2O_TYPE_PCI)
1915
        {
1916
                struct resource *root;
1917
 
1918
                if(iop->status_block->current_mem_size < iop->status_block->desired_mem_size)
1919
                {
1920
                        struct resource *res = &iop->mem_resource;
1921
                        res->name = iop->pdev->bus->name;
1922
                        res->flags = IORESOURCE_MEM;
1923
                        res->start = 0;
1924
                        res->end = 0;
1925
                        printk("%s: requires private memory resources.\n", iop->name);
1926
                        root = pci_find_parent_resource(iop->pdev, res);
1927
                        if(root==NULL)
1928
                                printk("Can't find parent resource!\n");
1929
                        if(root && allocate_resource(root, res,
1930
                                        iop->status_block->desired_mem_size,
1931
                                        iop->status_block->desired_mem_size,
1932
                                        iop->status_block->desired_mem_size,
1933
                                        1<<20,  /* Unspecified, so use 1Mb and play safe */
1934
                                        NULL,
1935
                                        NULL)>=0)
1936
                        {
1937
                                iop->mem_alloc = 1;
1938
                                iop->status_block->current_mem_size = 1 + res->end - res->start;
1939
                                iop->status_block->current_mem_base = res->start;
1940
                                printk(KERN_INFO "%s: allocated %ld bytes of PCI memory at 0x%08lX.\n",
1941
                                        iop->name, 1+res->end-res->start, res->start);
1942
                        }
1943
                }
1944
                if(iop->status_block->current_io_size < iop->status_block->desired_io_size)
1945
                {
1946
                        struct resource *res = &iop->io_resource;
1947
                        res->name = iop->pdev->bus->name;
1948
                        res->flags = IORESOURCE_IO;
1949
                        res->start = 0;
1950
                        res->end = 0;
1951
                        printk("%s: requires private memory resources.\n", iop->name);
1952
                        root = pci_find_parent_resource(iop->pdev, res);
1953
                        if(root==NULL)
1954
                                printk("Can't find parent resource!\n");
1955
                        if(root &&  allocate_resource(root, res,
1956
                                        iop->status_block->desired_io_size,
1957
                                        iop->status_block->desired_io_size,
1958
                                        iop->status_block->desired_io_size,
1959
                                        1<<20,  /* Unspecified, so use 1Mb and play safe */
1960
                                        NULL,
1961
                                        NULL)>=0)
1962
                        {
1963
                                iop->io_alloc = 1;
1964
                                iop->status_block->current_io_size = 1 + res->end - res->start;
1965
                                iop->status_block->current_mem_base = res->start;
1966
                                printk(KERN_INFO "%s: allocated %ld bytes of PCI I/O at 0x%08lX.\n",
1967
                                        iop->name, 1+res->end-res->start, res->start);
1968
                        }
1969
                }
1970
        }
1971
        else
1972
        {
1973
                privbuf[0] = iop->status_block->current_mem_base;
1974
                privbuf[1] = iop->status_block->current_mem_size;
1975
                privbuf[2] = iop->status_block->current_io_base;
1976
                privbuf[3] = iop->status_block->current_io_size;
1977
        }
1978
 
1979
        msg[0] = I2O_MESSAGE_SIZE(12) | SGL_OFFSET_6;
1980
        msg[1] = I2O_CMD_SYS_TAB_SET<<24 | HOST_TID<<12 | ADAPTER_TID;
1981
        msg[3] = 0;
1982
        msg[4] = (0<<16) | ((iop->unit+2) );      /* Host 0 IOP ID (unit + 2) */
1983
        msg[5] = 0;                               /* Segment 0 */
1984
 
1985
        /*
1986
         * Provide three SGL-elements:
1987
         * System table (SysTab), Private memory space declaration and
1988
         * Private i/o space declaration
1989
         *
1990
         * FIXME: provide these for controllers needing them
1991
         */
1992
        msg[6] = 0x54000000 | sys_tbl_len;
1993
        msg[7] = virt_to_bus(sys_tbl);
1994
        msg[8] = 0x54000000 | privbuf[1];
1995
        msg[9] = privbuf[0];
1996
        msg[10] = 0xD4000000 | privbuf[3];
1997
        msg[11] = privbuf[2];
1998
 
1999
        ret=i2o_post_wait_mem(iop, msg, sizeof(msg), 120, privbuf, NULL);
2000
 
2001
        if(ret==-ETIMEDOUT)
2002
        {
2003
                printk(KERN_ERR "%s: SysTab setup timed out.\n", iop->name);
2004
        }
2005
        else if(ret<0)
2006
        {
2007
                printk(KERN_ERR "%s: Unable to set SysTab (status=%#x).\n",
2008
                        iop->name, -ret);
2009
                kfree(privbuf);
2010
        }
2011
        else
2012
        {
2013
                dprintk(KERN_INFO "%s: SysTab set.\n", iop->name);
2014
                kfree(privbuf);
2015
        }
2016
        i2o_status_get(iop); // Entered READY state
2017
 
2018
        return ret;
2019
 
2020
 }
2021
 
2022
/*
2023
 * Initialize I2O subsystem.
2024
 */
2025
void __init i2o_sys_init(void)
2026
{
2027
        struct i2o_controller *iop, *niop = NULL;
2028
 
2029
        printk(KERN_INFO "Activating I2O controllers...\n");
2030
        printk(KERN_INFO "This may take a few minutes if there are many devices\n");
2031
 
2032
        /* In INIT state, Activate IOPs */
2033
        for (iop = i2o_controller_chain; iop; iop = niop) {
2034
                dprintk(KERN_INFO "Calling i2o_activate_controller for %s...\n",
2035
                        iop->name);
2036
                niop = iop->next;
2037
                if (i2o_activate_controller(iop) < 0)
2038
                        i2o_delete_controller(iop);
2039
        }
2040
 
2041
        /* Active IOPs in HOLD state */
2042
 
2043
rebuild_sys_tab:
2044
        if (i2o_controller_chain == NULL)
2045
                return;
2046
 
2047
        /*
2048
         * If build_sys_table fails, we kill everything and bail
2049
         * as we can't init the IOPs w/o a system table
2050
         */
2051
        dprintk(KERN_INFO "i2o_core: Calling i2o_build_sys_table...\n");
2052
        if (i2o_build_sys_table() < 0) {
2053
                i2o_sys_shutdown();
2054
                return;
2055
        }
2056
 
2057
        /* If IOP don't get online, we need to rebuild the System table */
2058
        for (iop = i2o_controller_chain; iop; iop = niop) {
2059
                niop = iop->next;
2060
                dprintk(KERN_INFO "Calling i2o_online_controller for %s...\n", iop->name);
2061
                if (i2o_online_controller(iop) < 0) {
2062
                        i2o_delete_controller(iop);
2063
                        goto rebuild_sys_tab;
2064
                }
2065
        }
2066
 
2067
        /* Active IOPs now in OPERATIONAL state */
2068
 
2069
        /*
2070
         * Register for status updates from all IOPs
2071
         */
2072
        for(iop = i2o_controller_chain; iop; iop=iop->next) {
2073
 
2074
                /* Create a kernel thread to deal with dynamic LCT updates */
2075
                iop->lct_pid = kernel_thread(i2o_dyn_lct, iop, CLONE_SIGHAND);
2076
 
2077
                /* Update change ind on DLCT */
2078
                iop->dlct->change_ind = iop->lct->change_ind;
2079
 
2080
                /* Start dynamic LCT updates */
2081
                i2o_lct_notify(iop);
2082
 
2083
                /* Register for all events from IRTOS */
2084
                i2o_event_register(iop, core_context, 0, 0, 0xFFFFFFFF);
2085
        }
2086
}
2087
 
2088
/**
2089
 *      i2o_sys_shutdown - shutdown I2O system
2090
 *
2091
 *      Bring down each i2o controller and then return. Each controller
2092
 *      is taken through an orderly shutdown
2093
 */
2094
 
2095
static void i2o_sys_shutdown(void)
2096
{
2097
        struct i2o_controller *iop, *niop;
2098
 
2099
        /* Delete all IOPs from the controller chain */
2100
        /* that will reset all IOPs too */
2101
 
2102
        for (iop = i2o_controller_chain; iop; iop = niop) {
2103
                niop = iop->next;
2104
                i2o_delete_controller(iop);
2105
        }
2106
}
2107
 
2108
/**
2109
 *      i2o_activate_controller -       bring controller up to HOLD
2110
 *      @iop: controller
2111
 *
2112
 *      This function brings an I2O controller into HOLD state. The adapter
2113
 *      is reset if neccessary and then the queues and resource table
2114
 *      are read. -1 is returned on a failure, 0 on success.
2115
 *
2116
 */
2117
 
2118
int i2o_activate_controller(struct i2o_controller *iop)
2119
{
2120
        /* In INIT state, Wait Inbound Q to initialize (in i2o_status_get) */
2121
        /* In READY state, Get status */
2122
 
2123
        if (i2o_status_get(iop) < 0) {
2124
                printk(KERN_INFO "Unable to obtain status of %s, "
2125
                        "attempting a reset.\n", iop->name);
2126
                if (i2o_reset_controller(iop) < 0)
2127
                        return -1;
2128
        }
2129
 
2130
        if(iop->status_block->iop_state == ADAPTER_STATE_FAULTED) {
2131
                printk(KERN_CRIT "%s: hardware fault\n", iop->name);
2132
                return -1;
2133
        }
2134
 
2135
        if (iop->status_block->i2o_version > I2OVER15) {
2136
                printk(KERN_ERR "%s: Not running vrs. 1.5. of the I2O Specification.\n",
2137
                        iop->name);
2138
                return -1;
2139
        }
2140
 
2141
        if (iop->status_block->iop_state == ADAPTER_STATE_READY ||
2142
            iop->status_block->iop_state == ADAPTER_STATE_OPERATIONAL ||
2143
            iop->status_block->iop_state == ADAPTER_STATE_HOLD ||
2144
            iop->status_block->iop_state == ADAPTER_STATE_FAILED)
2145
        {
2146
                dprintk(KERN_INFO "%s: Already running, trying to reset...\n",
2147
                        iop->name);
2148
                if (i2o_reset_controller(iop) < 0)
2149
                        return -1;
2150
        }
2151
 
2152
        if (i2o_init_outbound_q(iop) < 0)
2153
                return -1;
2154
 
2155
        if (i2o_post_outbound_messages(iop))
2156
                return -1;
2157
 
2158
        /* In HOLD state */
2159
 
2160
        if (i2o_hrt_get(iop) < 0)
2161
                return -1;
2162
 
2163
        return 0;
2164
}
2165
 
2166
 
2167
/**
2168
 *      i2o_init_outbound_queue - setup the outbound queue
2169
 *      @c: controller
2170
 *
2171
 *      Clear and (re)initialize IOP's outbound queue. Returns 0 on
2172
 *      success or a negative errno code on a failure.
2173
 */
2174
 
2175
int i2o_init_outbound_q(struct i2o_controller *c)
2176
{
2177
        u8 *status;
2178
        u32 m;
2179
        u32 *msg;
2180
        u32 time;
2181
 
2182
        dprintk(KERN_INFO "%s: Initializing Outbound Queue...\n", c->name);
2183
        m=i2o_wait_message(c, "OutboundInit");
2184
        if(m==0xFFFFFFFF)
2185
                return -ETIMEDOUT;
2186
        msg=(u32 *)(c->mem_offset+m);
2187
 
2188
        status = kmalloc(4,GFP_KERNEL);
2189
        if (status==NULL) {
2190
                printk(KERN_ERR "%s: Outbound Queue initialization failed - no free memory.\n",
2191
                        c->name);
2192
                return -ENOMEM;
2193
        }
2194
        memset(status, 0, 4);
2195
 
2196
        msg[0]= EIGHT_WORD_MSG_SIZE| TRL_OFFSET_6;
2197
        msg[1]= I2O_CMD_OUTBOUND_INIT<<24 | HOST_TID<<12 | ADAPTER_TID;
2198
        msg[2]= core_context;
2199
        msg[3]= 0x0106;                         /* Transaction context */
2200
        msg[4]= 4096;                           /* Host page frame size */
2201
        /* Frame size is in words. 256 bytes a frame for now */
2202
        msg[5]= MSG_FRAME_SIZE<<16|0x80;        /* Outbound msg frame size in words and Initcode */
2203
        msg[6]= 0xD0000004;                     /* Simple SG LE, EOB */
2204
        msg[7]= virt_to_bus(status);
2205
 
2206
        i2o_post_message(c,m);
2207
 
2208
        barrier();
2209
        time=jiffies;
2210
        while(status[0] < I2O_CMD_REJECTED)
2211
        {
2212
                if((jiffies-time)>=30*HZ)
2213
                {
2214
                        if(status[0]==0x00)
2215
                                printk(KERN_ERR "%s: Ignored queue initialize request.\n",
2216
                                        c->name);
2217
                        else
2218
                                printk(KERN_ERR "%s: Outbound queue initialize timeout.\n",
2219
                                        c->name);
2220
                        kfree(status);
2221
                        return -ETIMEDOUT;
2222
                }
2223
                schedule();
2224
                barrier();
2225
        }
2226
 
2227
        if(status[0] != I2O_CMD_COMPLETED)
2228
        {
2229
                printk(KERN_ERR "%s: IOP outbound initialise failed.\n", c->name);
2230
                kfree(status);
2231
                return -ETIMEDOUT;
2232
        }
2233
 
2234
        kfree(status);
2235
        return 0;
2236
}
2237
 
2238
/**
2239
 *      i2o_post_outbound_messages      -       fill message queue
2240
 *      @c: controller
2241
 *
2242
 *      Allocate a message frame and load the messages into the IOP. The
2243
 *      function returns zero on success or a negative errno code on
2244
 *      failure.
2245
 */
2246
 
2247
int i2o_post_outbound_messages(struct i2o_controller *c)
2248
{
2249
        int i;
2250
        u32 m;
2251
        /* Alloc space for IOP's outbound queue message frames */
2252
 
2253
        c->page_frame = kmalloc(MSG_POOL_SIZE, GFP_KERNEL);
2254
        if(c->page_frame==NULL) {
2255
                printk(KERN_ERR "%s: Outbound Q initialize failed; out of memory.\n",
2256
                        c->name);
2257
                return -ENOMEM;
2258
        }
2259
 
2260
        c->page_frame_map = pci_map_single(c->pdev, c->page_frame, MSG_POOL_SIZE, PCI_DMA_FROMDEVICE);
2261
 
2262
        if(c->page_frame_map == 0)
2263
        {
2264
                kfree(c->page_frame);
2265
                printk(KERN_ERR "%s: Unable to map outbound queue.\n", c->name);
2266
                return -ENOMEM;
2267
        }
2268
 
2269
        m = c->page_frame_map;
2270
 
2271
        /* Post frames */
2272
 
2273
        for(i=0; i< NMBR_MSG_FRAMES; i++) {
2274
                I2O_REPLY_WRITE32(c,m);
2275
                mb();
2276
                m += (MSG_FRAME_SIZE << 2);
2277
        }
2278
 
2279
        return 0;
2280
}
2281
 
2282
/*
2283
 * Get the IOP's Logical Configuration Table
2284
 */
2285
int i2o_lct_get(struct i2o_controller *c)
2286
{
2287
        u32 msg[8];
2288
        int ret, size = c->status_block->expected_lct_size;
2289
 
2290
        do {
2291
                if (c->lct == NULL) {
2292
                        c->lct = kmalloc(size, GFP_KERNEL);
2293
                        if(c->lct == NULL) {
2294
                                printk(KERN_CRIT "%s: Lct Get failed. Out of memory.\n",
2295
                                        c->name);
2296
                                return -ENOMEM;
2297
                        }
2298
                }
2299
                memset(c->lct, 0, size);
2300
 
2301
                msg[0] = EIGHT_WORD_MSG_SIZE|SGL_OFFSET_6;
2302
                msg[1] = I2O_CMD_LCT_NOTIFY<<24 | HOST_TID<<12 | ADAPTER_TID;
2303
                /* msg[2] filled in i2o_post_wait */
2304
                msg[3] = 0;
2305
                msg[4] = 0xFFFFFFFF;    /* All devices */
2306
                msg[5] = 0x00000000;    /* Report now */
2307
                msg[6] = 0xD0000000|size;
2308
                msg[7] = virt_to_bus(c->lct);
2309
 
2310
                ret=i2o_post_wait_mem(c, msg, sizeof(msg), 120, c->lct, NULL);
2311
 
2312
                if(ret == -ETIMEDOUT)
2313
                {
2314
                        c->lct = NULL;
2315
                        return ret;
2316
                }
2317
 
2318
                if(ret<0)
2319
                {
2320
                        printk(KERN_ERR "%s: LCT Get failed (status=%#x.\n",
2321
                                c->name, -ret);
2322
                        return ret;
2323
                }
2324
 
2325
                if (c->lct->table_size << 2 > size) {
2326
                        size = c->lct->table_size << 2;
2327
                        kfree(c->lct);
2328
                        c->lct = NULL;
2329
                }
2330
        } while (c->lct == NULL);
2331
 
2332
        if ((ret=i2o_parse_lct(c)) < 0)
2333
                return ret;
2334
 
2335
        return 0;
2336
}
2337
 
2338
/*
2339
 * Like above, but used for async notification.  The main
2340
 * difference is that we keep track of the CurrentChangeIndiicator
2341
 * so that we only get updates when it actually changes.
2342
 *
2343
 */
2344
int i2o_lct_notify(struct i2o_controller *c)
2345
{
2346
        u32 msg[8];
2347
 
2348
        msg[0] = EIGHT_WORD_MSG_SIZE|SGL_OFFSET_6;
2349
        msg[1] = I2O_CMD_LCT_NOTIFY<<24 | HOST_TID<<12 | ADAPTER_TID;
2350
        msg[2] = core_context;
2351
        msg[3] = 0xDEADBEEF;
2352
        msg[4] = 0xFFFFFFFF;    /* All devices */
2353
        msg[5] = c->dlct->change_ind+1; /* Next change */
2354
        msg[6] = 0xD0000000|8192;
2355
        msg[7] = virt_to_bus(c->dlct);
2356
 
2357
        return i2o_post_this(c, msg, sizeof(msg));
2358
}
2359
 
2360
/*
2361
 *      Bring a controller online into OPERATIONAL state.
2362
 */
2363
 
2364
int i2o_online_controller(struct i2o_controller *iop)
2365
{
2366
        u32 v;
2367
 
2368
        if (i2o_systab_send(iop) < 0)
2369
                return -1;
2370
 
2371
        /* In READY state */
2372
 
2373
        dprintk(KERN_INFO "%s: Attempting to enable...\n", iop->name);
2374
        if (i2o_enable_controller(iop) < 0)
2375
                return -1;
2376
 
2377
        /* In OPERATIONAL state  */
2378
 
2379
        dprintk(KERN_INFO "%s: Attempting to get/parse lct...\n", iop->name);
2380
        if (i2o_lct_get(iop) < 0)
2381
                return -1;
2382
 
2383
        /* Check battery status */
2384
 
2385
        iop->battery = 0;
2386
        if(i2o_query_scalar(iop, ADAPTER_TID, 0x0000, 4, &v, 4)>=0)
2387
        {
2388
                if(v&16)
2389
                        iop->battery = 1;
2390
        }
2391
 
2392
        return 0;
2393
}
2394
 
2395
/*
2396
 * Build system table
2397
 *
2398
 * The system table contains information about all the IOPs in the
2399
 * system (duh) and is used by the Executives on the IOPs to establish
2400
 * peer2peer connections.  We're not supporting peer2peer at the moment,
2401
 * but this will be needed down the road for things like lan2lan forwarding.
2402
 */
2403
static int i2o_build_sys_table(void)
2404
{
2405
        struct i2o_controller *iop = NULL;
2406
        struct i2o_controller *niop = NULL;
2407
        int count = 0;
2408
 
2409
        sys_tbl_len = sizeof(struct i2o_sys_tbl) +      // Header + IOPs
2410
                                (i2o_num_controllers) *
2411
                                        sizeof(struct i2o_sys_tbl_entry);
2412
 
2413
        if(sys_tbl)
2414
                kfree(sys_tbl);
2415
 
2416
        sys_tbl = kmalloc(sys_tbl_len, GFP_KERNEL);
2417
        if(!sys_tbl) {
2418
                printk(KERN_CRIT "SysTab Set failed. Out of memory.\n");
2419
                return -ENOMEM;
2420
        }
2421
        memset((void*)sys_tbl, 0, sys_tbl_len);
2422
 
2423
        sys_tbl->num_entries = i2o_num_controllers;
2424
        sys_tbl->version = I2OVERSION; /* TODO: Version 2.0 */
2425
        sys_tbl->change_ind = sys_tbl_ind++;
2426
 
2427
        for(iop = i2o_controller_chain; iop; iop = niop)
2428
        {
2429
                niop = iop->next;
2430
 
2431
                /*
2432
                 * Get updated IOP state so we have the latest information
2433
                 *
2434
                 * We should delete the controller at this point if it
2435
                 * doesn't respond since  if it's not on the system table
2436
                 * it is techninically not part of the I2O subsyßtem...
2437
                 */
2438
                if(i2o_status_get(iop)) {
2439
                        printk(KERN_ERR "%s: Deleting b/c could not get status while"
2440
                                "attempting to build system table\n", iop->name);
2441
                        i2o_delete_controller(iop);
2442
                        sys_tbl->num_entries--;
2443
                        continue; // try the next one
2444
                }
2445
 
2446
                sys_tbl->iops[count].org_id = iop->status_block->org_id;
2447
                sys_tbl->iops[count].iop_id = iop->unit + 2;
2448
                sys_tbl->iops[count].seg_num = 0;
2449
                sys_tbl->iops[count].i2o_version =
2450
                                iop->status_block->i2o_version;
2451
                sys_tbl->iops[count].iop_state =
2452
                                iop->status_block->iop_state;
2453
                sys_tbl->iops[count].msg_type =
2454
                                iop->status_block->msg_type;
2455
                sys_tbl->iops[count].frame_size =
2456
                                iop->status_block->inbound_frame_size;
2457
                sys_tbl->iops[count].last_changed = sys_tbl_ind - 1; // ??
2458
                sys_tbl->iops[count].iop_capabilities =
2459
                                iop->status_block->iop_capabilities;
2460
                sys_tbl->iops[count].inbound_low = iop->post_port;
2461
                sys_tbl->iops[count].inbound_high = 0;   // FIXME: 64-bit support
2462
 
2463
                count++;
2464
        }
2465
 
2466
#ifdef DRIVERDEBUG
2467
{
2468
        u32 *table;
2469
        table = (u32*)sys_tbl;
2470
        for(count = 0; count < (sys_tbl_len >>2); count++)
2471
                printk(KERN_INFO "sys_tbl[%d] = %0#10x\n", count, table[count]);
2472
}
2473
#endif
2474
 
2475
        return 0;
2476
}
2477
 
2478
 
2479
/*
2480
 *      Run time support routines
2481
 */
2482
 
2483
/*
2484
 *      Generic "post and forget" helpers. This is less efficient - we do
2485
 *      a memcpy for example that isnt strictly needed, but for most uses
2486
 *      this is simply not worth optimising
2487
 */
2488
 
2489
int i2o_post_this(struct i2o_controller *c, u32 *data, int len)
2490
{
2491
        u32 m;
2492
        u32 *msg;
2493
        unsigned long t=jiffies;
2494
 
2495
        do
2496
        {
2497
                mb();
2498
                m = I2O_POST_READ32(c);
2499
        }
2500
        while(m==0xFFFFFFFF && (jiffies-t)<HZ);
2501
 
2502
        if(m==0xFFFFFFFF)
2503
        {
2504
                printk(KERN_ERR "%s: Timeout waiting for message frame!\n",
2505
                       c->name);
2506
                return -ETIMEDOUT;
2507
        }
2508
        msg = (u32 *)(c->mem_offset + m);
2509
        memcpy_toio(msg, data, len);
2510
        i2o_post_message(c,m);
2511
        return 0;
2512
}
2513
 
2514
/**
2515
 *      i2o_post_wait_mem       -       I2O query/reply with DMA buffers
2516
 *      @c: controller
2517
 *      @msg: message to send
2518
 *      @len: length of message
2519
 *      @timeout: time in seconds to wait
2520
 *      @mem1: attached memory buffer 1
2521
 *      @mem2: attached memory buffer 2
2522
 *
2523
 *      This core API allows an OSM to post a message and then be told whether
2524
 *      or not the system received a successful reply.
2525
 *
2526
 *      If the message times out then the value '-ETIMEDOUT' is returned. This
2527
 *      is a special case. In this situation the message may (should) complete
2528
 *      at an indefinite time in the future. When it completes it will use the
2529
 *      memory buffers attached to the request. If -ETIMEDOUT is returned then
2530
 *      the memory buffers must not be freed. Instead the event completion will
2531
 *      free them for you. In all other cases the buffers are your problem.
2532
 *
2533
 *      Pass NULL for unneeded buffers.
2534
 */
2535
 
2536
int i2o_post_wait_mem(struct i2o_controller *c, u32 *msg, int len, int timeout, void *mem1, void *mem2)
2537
{
2538
        DECLARE_WAIT_QUEUE_HEAD(wq_i2o_post);
2539
        DECLARE_WAITQUEUE(wait, current);
2540
        int complete = 0;
2541
        int status;
2542
        unsigned long flags = 0;
2543
        struct i2o_post_wait_data *wait_data =
2544
                kmalloc(sizeof(struct i2o_post_wait_data), GFP_KERNEL);
2545
 
2546
        if(!wait_data)
2547
                return -ENOMEM;
2548
 
2549
        /*
2550
         *      Create a new notification object
2551
         */
2552
        wait_data->status = &status;
2553
        wait_data->complete = &complete;
2554
        wait_data->mem[0] = mem1;
2555
        wait_data->mem[1] = mem2;
2556
        /*
2557
         *      Queue the event with its unique id
2558
         */
2559
        spin_lock_irqsave(&post_wait_lock, flags);
2560
 
2561
        wait_data->next = post_wait_queue;
2562
        post_wait_queue = wait_data;
2563
        wait_data->id = (++post_wait_id) & 0x7fff;
2564
        wait_data->wq = &wq_i2o_post;
2565
 
2566
        spin_unlock_irqrestore(&post_wait_lock, flags);
2567
 
2568
        /*
2569
         *      Fill in the message id
2570
         */
2571
 
2572
        msg[2] = 0x80000000|(u32)core_context|((u32)wait_data->id<<16);
2573
 
2574
        /*
2575
         *      Post the message to the controller. At some point later it
2576
         *      will return. If we time out before it returns then
2577
         *      complete will be zero.  From the point post_this returns
2578
         *      the wait_data may have been deleted.
2579
         */
2580
 
2581
        add_wait_queue(&wq_i2o_post, &wait);
2582
        set_current_state(TASK_INTERRUPTIBLE);
2583
        if ((status = i2o_post_this(c, msg, len))==0) {
2584
                schedule_timeout(HZ * timeout);
2585
        }
2586
        else
2587
        {
2588
                remove_wait_queue(&wq_i2o_post, &wait);
2589
                return -EIO;
2590
        }
2591
        remove_wait_queue(&wq_i2o_post, &wait);
2592
 
2593
        if(signal_pending(current))
2594
                status = -EINTR;
2595
 
2596
        spin_lock_irqsave(&post_wait_lock, flags);
2597
        barrier();      /* Be sure we see complete as it is locked */
2598
        if(!complete)
2599
        {
2600
                /*
2601
                 *      Mark the entry dead. We cannot remove it. This is important.
2602
                 *      When it does terminate (which it must do if the controller hasnt
2603
                 *      died..) then it will otherwise scribble on stuff.
2604
                 *      !complete lets us safely check if the entry is still
2605
                 *      allocated and thus we can write into it
2606
                 */
2607
                wait_data->wq = NULL;
2608
                status = -ETIMEDOUT;
2609
        }
2610
        else
2611
        {
2612
                /* Debugging check - remove me soon */
2613
                if(status == -ETIMEDOUT)
2614
                {
2615
                        printk("TIMEDOUT BUG!\n");
2616
                        status = -EIO;
2617
                }
2618
        }
2619
        /* And the wait_data is not leaked either! */
2620
        spin_unlock_irqrestore(&post_wait_lock, flags);
2621
        return status;
2622
}
2623
 
2624
/**
2625
 *      i2o_post_wait           -       I2O query/reply
2626
 *      @c: controller
2627
 *      @msg: message to send
2628
 *      @len: length of message
2629
 *      @timeout: time in seconds to wait
2630
 *
2631
 *      This core API allows an OSM to post a message and then be told whether
2632
 *      or not the system received a successful reply.
2633
 */
2634
 
2635
int i2o_post_wait(struct i2o_controller *c, u32 *msg, int len, int timeout)
2636
{
2637
        return i2o_post_wait_mem(c, msg, len, timeout, NULL, NULL);
2638
}
2639
 
2640
/*
2641
 * i2o_post_wait is completed and we want to wake up the
2642
 * sleeping proccess. Called by core's reply handler.
2643
 */
2644
 
2645
static void i2o_post_wait_complete(u32 context, int status)
2646
{
2647
        struct i2o_post_wait_data **p1, *q;
2648
        unsigned long flags;
2649
 
2650
        /*
2651
         * We need to search through the post_wait
2652
         * queue to see if the given message is still
2653
         * outstanding.  If not, it means that the IOP
2654
         * took longer to respond to the message than we
2655
         * had allowed and timer has already expired.
2656
         * Not much we can do about that except log
2657
         * it for debug purposes, increase timeout, and recompile
2658
         *
2659
         * Lock needed to keep anyone from moving queue pointers
2660
         * around while we're looking through them.
2661
         */
2662
 
2663
        spin_lock_irqsave(&post_wait_lock, flags);
2664
 
2665
        for(p1 = &post_wait_queue; *p1!=NULL; p1 = &((*p1)->next))
2666
        {
2667
                q = (*p1);
2668
                if(q->id == ((context >> 16) & 0x7fff)) {
2669
                        /*
2670
                         *      Delete it
2671
                         */
2672
 
2673
                        *p1 = q->next;
2674
 
2675
                        /*
2676
                         *      Live or dead ?
2677
                         */
2678
 
2679
                        if(q->wq)
2680
                        {
2681
                                /* Live entry - wakeup and set status */
2682
                                *q->status = status;
2683
                                *q->complete = 1;
2684
                                wake_up(q->wq);
2685
                        }
2686
                        else
2687
                        {
2688
                                /*
2689
                                 *      Free resources. Caller is dead
2690
                                 */
2691
                                if(q->mem[0])
2692
                                        kfree(q->mem[0]);
2693
                                if(q->mem[1])
2694
                                        kfree(q->mem[1]);
2695
                                printk(KERN_WARNING "i2o_post_wait event completed after timeout.\n");
2696
                        }
2697
                        kfree(q);
2698
                        spin_unlock(&post_wait_lock);
2699
                        return;
2700
                }
2701
        }
2702
        spin_unlock(&post_wait_lock);
2703
 
2704
        printk(KERN_DEBUG "i2o_post_wait: Bogus reply!\n");
2705
}
2706
 
2707
/*      Issue UTIL_PARAMS_GET or UTIL_PARAMS_SET
2708
 *
2709
 *      This function can be used for all UtilParamsGet/Set operations.
2710
 *      The OperationList is given in oplist-buffer,
2711
 *      and results are returned in reslist-buffer.
2712
 *      Note that the minimum sized reslist is 8 bytes and contains
2713
 *      ResultCount, ErrorInfoSize, BlockStatus and BlockSize.
2714
 */
2715
int i2o_issue_params(int cmd, struct i2o_controller *iop, int tid,
2716
                void *oplist, int oplen, void *reslist, int reslen)
2717
{
2718
        u32 msg[9];
2719
        u32 *res32 = (u32*)reslist;
2720
        u32 *restmp = (u32*)reslist;
2721
        int len = 0;
2722
        int i = 0;
2723
        int wait_status;
2724
        u32 *opmem, *resmem;
2725
 
2726
        /* Get DMAable memory */
2727
        opmem = kmalloc(oplen, GFP_KERNEL);
2728
        if(opmem == NULL)
2729
                return -ENOMEM;
2730
        memcpy(opmem, oplist, oplen);
2731
 
2732
        resmem = kmalloc(reslen, GFP_KERNEL);
2733
        if(resmem == NULL)
2734
        {
2735
                kfree(opmem);
2736
                return -ENOMEM;
2737
        }
2738
 
2739
        msg[0] = NINE_WORD_MSG_SIZE | SGL_OFFSET_5;
2740
        msg[1] = cmd << 24 | HOST_TID << 12 | tid;
2741
        msg[3] = 0;
2742
        msg[4] = 0;
2743
        msg[5] = 0x54000000 | oplen;    /* OperationList */
2744
        msg[6] = virt_to_bus(opmem);
2745
        msg[7] = 0xD0000000 | reslen;   /* ResultList */
2746
        msg[8] = virt_to_bus(resmem);
2747
 
2748
        wait_status = i2o_post_wait_mem(iop, msg, sizeof(msg), 10, opmem, resmem);
2749
 
2750
        /*
2751
         *      This only looks like a memory leak - don't "fix" it.
2752
         */
2753
        if(wait_status == -ETIMEDOUT)
2754
                return wait_status;
2755
 
2756
        /* Query failed */
2757
        if(wait_status != 0)
2758
        {
2759
                kfree(resmem);
2760
                kfree(opmem);
2761
                return wait_status;
2762
        }
2763
 
2764
        memcpy(reslist, resmem, reslen);
2765
        /*
2766
         * Calculate number of bytes of Result LIST
2767
         * We need to loop through each Result BLOCK and grab the length
2768
         */
2769
        restmp = res32 + 1;
2770
        len = 1;
2771
        for(i = 0; i < (res32[0]&0X0000FFFF); i++)
2772
        {
2773
                if(restmp[0]&0x00FF0000) /* BlockStatus != SUCCESS */
2774
                {
2775
                        printk(KERN_WARNING "%s - Error:\n  ErrorInfoSize = 0x%02x, "
2776
                                        "BlockStatus = 0x%02x, BlockSize = 0x%04x\n",
2777
                                        (cmd == I2O_CMD_UTIL_PARAMS_SET) ? "PARAMS_SET"
2778
                                        : "PARAMS_GET",
2779
                                        res32[1]>>24, (res32[1]>>16)&0xFF, res32[1]&0xFFFF);
2780
 
2781
                        /*
2782
                         *      If this is the only request,than we return an error
2783
                         */
2784
                        if((res32[0]&0x0000FFFF) == 1)
2785
                        {
2786
                                return -((res32[1] >> 16) & 0xFF); /* -BlockStatus */
2787
                        }
2788
                }
2789
                len += restmp[0] & 0x0000FFFF;   /* Length of res BLOCK */
2790
                restmp += restmp[0] & 0x0000FFFF;        /* Skip to next BLOCK */
2791
        }
2792
        return (len << 2);  /* bytes used by result list */
2793
}
2794
 
2795
/*
2796
 *       Query one scalar group value or a whole scalar group.
2797
 */
2798
int i2o_query_scalar(struct i2o_controller *iop, int tid,
2799
                     int group, int field, void *buf, int buflen)
2800
{
2801
        u16 opblk[] = { 1, 0, I2O_PARAMS_FIELD_GET, group, 1, field };
2802
        u8  resblk[8+buflen]; /* 8 bytes for header */
2803
        int size;
2804
 
2805
        if (field == -1)                /* whole group */
2806
                opblk[4] = -1;
2807
 
2808
        size = i2o_issue_params(I2O_CMD_UTIL_PARAMS_GET, iop, tid,
2809
                opblk, sizeof(opblk), resblk, sizeof(resblk));
2810
 
2811
        memcpy(buf, resblk+8, buflen);  /* cut off header */
2812
 
2813
        if(size>buflen)
2814
                return buflen;
2815
        return size;
2816
}
2817
 
2818
/*
2819
 *      Set a scalar group value or a whole group.
2820
 */
2821
int i2o_set_scalar(struct i2o_controller *iop, int tid,
2822
                   int group, int field, void *buf, int buflen)
2823
{
2824
        u16 *opblk;
2825
        u8  resblk[8+buflen]; /* 8 bytes for header */
2826
        int size;
2827
 
2828
        opblk = kmalloc(buflen+64, GFP_KERNEL);
2829
        if (opblk == NULL)
2830
        {
2831
                printk(KERN_ERR "i2o: no memory for operation buffer.\n");
2832
                return -ENOMEM;
2833
        }
2834
 
2835
        opblk[0] = 1;                        /* operation count */
2836
        opblk[1] = 0;                        /* pad */
2837
        opblk[2] = I2O_PARAMS_FIELD_SET;
2838
        opblk[3] = group;
2839
 
2840
        if(field == -1) {               /* whole group */
2841
                opblk[4] = -1;
2842
                memcpy(opblk+5, buf, buflen);
2843
        }
2844
        else                            /* single field */
2845
        {
2846
                opblk[4] = 1;
2847
                opblk[5] = field;
2848
                memcpy(opblk+6, buf, buflen);
2849
        }
2850
 
2851
        size = i2o_issue_params(I2O_CMD_UTIL_PARAMS_SET, iop, tid,
2852
                                opblk, 12+buflen, resblk, sizeof(resblk));
2853
 
2854
        kfree(opblk);
2855
        if(size>buflen)
2856
                return buflen;
2857
        return size;
2858
}
2859
 
2860
/*
2861
 *      if oper == I2O_PARAMS_TABLE_GET, get from all rows
2862
 *              if fieldcount == -1 return all fields
2863
 *                      ibuf and ibuflen are unused (use NULL, 0)
2864
 *              else return specific fields
2865
 *                      ibuf contains fieldindexes
2866
 *
2867
 *      if oper == I2O_PARAMS_LIST_GET, get from specific rows
2868
 *              if fieldcount == -1 return all fields
2869
 *                      ibuf contains rowcount, keyvalues
2870
 *              else return specific fields
2871
 *                      fieldcount is # of fieldindexes
2872
 *                      ibuf contains fieldindexes, rowcount, keyvalues
2873
 *
2874
 *      You could also use directly function i2o_issue_params().
2875
 */
2876
int i2o_query_table(int oper, struct i2o_controller *iop, int tid, int group,
2877
                int fieldcount, void *ibuf, int ibuflen,
2878
                void *resblk, int reslen)
2879
{
2880
        u16 *opblk;
2881
        int size;
2882
 
2883
        opblk = kmalloc(10 + ibuflen, GFP_KERNEL);
2884
        if (opblk == NULL)
2885
        {
2886
                printk(KERN_ERR "i2o: no memory for query buffer.\n");
2887
                return -ENOMEM;
2888
        }
2889
 
2890
        opblk[0] = 1;                            /* operation count */
2891
        opblk[1] = 0;                            /* pad */
2892
        opblk[2] = oper;
2893
        opblk[3] = group;
2894
        opblk[4] = fieldcount;
2895
        memcpy(opblk+5, ibuf, ibuflen);         /* other params */
2896
 
2897
        size = i2o_issue_params(I2O_CMD_UTIL_PARAMS_GET,iop, tid,
2898
                                opblk, 10+ibuflen, resblk, reslen);
2899
 
2900
        kfree(opblk);
2901
        if(size>reslen)
2902
                return reslen;
2903
        return size;
2904
}
2905
 
2906
/*
2907
 *      Clear table group, i.e. delete all rows.
2908
 */
2909
int i2o_clear_table(struct i2o_controller *iop, int tid, int group)
2910
{
2911
        u16 opblk[] = { 1, 0, I2O_PARAMS_TABLE_CLEAR, group };
2912
        u8  resblk[32]; /* min 8 bytes for result header */
2913
 
2914
        return i2o_issue_params(I2O_CMD_UTIL_PARAMS_SET, iop, tid,
2915
                                opblk, sizeof(opblk), resblk, sizeof(resblk));
2916
}
2917
 
2918
/*
2919
 *      Add a new row into a table group.
2920
 *
2921
 *      if fieldcount==-1 then we add whole rows
2922
 *              buf contains rowcount, keyvalues
2923
 *      else just specific fields are given, rest use defaults
2924
 *              buf contains fieldindexes, rowcount, keyvalues
2925
 */
2926
int i2o_row_add_table(struct i2o_controller *iop, int tid,
2927
                    int group, int fieldcount, void *buf, int buflen)
2928
{
2929
        u16 *opblk;
2930
        u8  resblk[32]; /* min 8 bytes for header */
2931
        int size;
2932
 
2933
        opblk = kmalloc(buflen+64, GFP_KERNEL);
2934
        if (opblk == NULL)
2935
        {
2936
                printk(KERN_ERR "i2o: no memory for operation buffer.\n");
2937
                return -ENOMEM;
2938
        }
2939
 
2940
        opblk[0] = 1;                    /* operation count */
2941
        opblk[1] = 0;                    /* pad */
2942
        opblk[2] = I2O_PARAMS_ROW_ADD;
2943
        opblk[3] = group;
2944
        opblk[4] = fieldcount;
2945
        memcpy(opblk+5, buf, buflen);
2946
 
2947
        size = i2o_issue_params(I2O_CMD_UTIL_PARAMS_SET, iop, tid,
2948
                                opblk, 10+buflen, resblk, sizeof(resblk));
2949
 
2950
        kfree(opblk);
2951
        if(size>buflen)
2952
                return buflen;
2953
        return size;
2954
}
2955
 
2956
 
2957
/*
2958
 * Used for error reporting/debugging purposes.
2959
 * Following fail status are common to all classes.
2960
 * The preserved message must be handled in the reply handler.
2961
 */
2962
void i2o_report_fail_status(u8 req_status, u32* msg)
2963
{
2964
        static char *FAIL_STATUS[] = {
2965
                "0x80",                         /* not used */
2966
                "SERVICE_SUSPENDED",            /* 0x81 */
2967
                "SERVICE_TERMINATED",           /* 0x82 */
2968
                "CONGESTION",
2969
                "FAILURE",
2970
                "STATE_ERROR",
2971
                "TIME_OUT",
2972
                "ROUTING_FAILURE",
2973
                "INVALID_VERSION",
2974
                "INVALID_OFFSET",
2975
                "INVALID_MSG_FLAGS",
2976
                "FRAME_TOO_SMALL",
2977
                "FRAME_TOO_LARGE",
2978
                "INVALID_TARGET_ID",
2979
                "INVALID_INITIATOR_ID",
2980
                "INVALID_INITIATOR_CONTEX",     /* 0x8F */
2981
                "UNKNOWN_FAILURE"               /* 0xFF */
2982
        };
2983
 
2984
        if (req_status == I2O_FSC_TRANSPORT_UNKNOWN_FAILURE)
2985
                printk("TRANSPORT_UNKNOWN_FAILURE (%0#2x)\n.", req_status);
2986
        else
2987
                printk("TRANSPORT_%s.\n", FAIL_STATUS[req_status & 0x0F]);
2988
 
2989
        /* Dump some details */
2990
 
2991
        printk(KERN_ERR "  InitiatorId = %d, TargetId = %d\n",
2992
                (msg[1] >> 12) & 0xFFF, msg[1] & 0xFFF);
2993
        printk(KERN_ERR "  LowestVersion = 0x%02X, HighestVersion = 0x%02X\n",
2994
                (msg[4] >> 8) & 0xFF, msg[4] & 0xFF);
2995
        printk(KERN_ERR "  FailingHostUnit = 0x%04X,  FailingIOP = 0x%03X\n",
2996
                msg[5] >> 16, msg[5] & 0xFFF);
2997
 
2998
        printk(KERN_ERR "  Severity:  0x%02X ", (msg[4] >> 16) & 0xFF);
2999
        if (msg[4] & (1<<16))
3000
                printk("(FormatError), "
3001
                        "this msg can never be delivered/processed.\n");
3002
        if (msg[4] & (1<<17))
3003
                printk("(PathError), "
3004
                        "this msg can no longer be delivered/processed.\n");
3005
        if (msg[4] & (1<<18))
3006
                printk("(PathState), "
3007
                        "the system state does not allow delivery.\n");
3008
        if (msg[4] & (1<<19))
3009
                printk("(Congestion), resources temporarily not available;"
3010
                        "do not retry immediately.\n");
3011
}
3012
 
3013
/*
3014
 * Used for error reporting/debugging purposes.
3015
 * Following reply status are common to all classes.
3016
 */
3017
void i2o_report_common_status(u8 req_status)
3018
{
3019
        static char *REPLY_STATUS[] = {
3020
                "SUCCESS",
3021
                "ABORT_DIRTY",
3022
                "ABORT_NO_DATA_TRANSFER",
3023
                "ABORT_PARTIAL_TRANSFER",
3024
                "ERROR_DIRTY",
3025
                "ERROR_NO_DATA_TRANSFER",
3026
                "ERROR_PARTIAL_TRANSFER",
3027
                "PROCESS_ABORT_DIRTY",
3028
                "PROCESS_ABORT_NO_DATA_TRANSFER",
3029
                "PROCESS_ABORT_PARTIAL_TRANSFER",
3030
                "TRANSACTION_ERROR",
3031
                "PROGRESS_REPORT"
3032
        };
3033
 
3034
        if (req_status > I2O_REPLY_STATUS_PROGRESS_REPORT)
3035
                printk("RequestStatus = %0#2x", req_status);
3036
        else
3037
                printk("%s", REPLY_STATUS[req_status]);
3038
}
3039
 
3040
/*
3041
 * Used for error reporting/debugging purposes.
3042
 * Following detailed status are valid  for executive class,
3043
 * utility class, DDM class and for transaction error replies.
3044
 */
3045
static void i2o_report_common_dsc(u16 detailed_status)
3046
{
3047
        static char *COMMON_DSC[] = {
3048
                "SUCCESS",
3049
                "0x01",                         // not used
3050
                "BAD_KEY",
3051
                "TCL_ERROR",
3052
                "REPLY_BUFFER_FULL",
3053
                "NO_SUCH_PAGE",
3054
                "INSUFFICIENT_RESOURCE_SOFT",
3055
                "INSUFFICIENT_RESOURCE_HARD",
3056
                "0x08",                         // not used
3057
                "CHAIN_BUFFER_TOO_LARGE",
3058
                "UNSUPPORTED_FUNCTION",
3059
                "DEVICE_LOCKED",
3060
                "DEVICE_RESET",
3061
                "INAPPROPRIATE_FUNCTION",
3062
                "INVALID_INITIATOR_ADDRESS",
3063
                "INVALID_MESSAGE_FLAGS",
3064
                "INVALID_OFFSET",
3065
                "INVALID_PARAMETER",
3066
                "INVALID_REQUEST",
3067
                "INVALID_TARGET_ADDRESS",
3068
                "MESSAGE_TOO_LARGE",
3069
                "MESSAGE_TOO_SMALL",
3070
                "MISSING_PARAMETER",
3071
                "TIMEOUT",
3072
                "UNKNOWN_ERROR",
3073
                "UNKNOWN_FUNCTION",
3074
                "UNSUPPORTED_VERSION",
3075
                "DEVICE_BUSY",
3076
                "DEVICE_NOT_AVAILABLE"
3077
        };
3078
 
3079
        if (detailed_status > I2O_DSC_DEVICE_NOT_AVAILABLE)
3080
                printk(" / DetailedStatus = %0#4x.\n", detailed_status);
3081
        else
3082
                printk(" / %s.\n", COMMON_DSC[detailed_status]);
3083
}
3084
 
3085
/*
3086
 * Used for error reporting/debugging purposes
3087
 */
3088
static void i2o_report_lan_dsc(u16 detailed_status)
3089
{
3090
        static char *LAN_DSC[] = {      // Lan detailed status code strings
3091
                "SUCCESS",
3092
                "DEVICE_FAILURE",
3093
                "DESTINATION_NOT_FOUND",
3094
                "TRANSMIT_ERROR",
3095
                "TRANSMIT_ABORTED",
3096
                "RECEIVE_ERROR",
3097
                "RECEIVE_ABORTED",
3098
                "DMA_ERROR",
3099
                "BAD_PACKET_DETECTED",
3100
                "OUT_OF_MEMORY",
3101
                "BUCKET_OVERRUN",
3102
                "IOP_INTERNAL_ERROR",
3103
                "CANCELED",
3104
                "INVALID_TRANSACTION_CONTEXT",
3105
                "DEST_ADDRESS_DETECTED",
3106
                "DEST_ADDRESS_OMITTED",
3107
                "PARTIAL_PACKET_RETURNED",
3108
                "TEMP_SUSPENDED_STATE", // last Lan detailed status code
3109
                "INVALID_REQUEST"       // general detailed status code
3110
        };
3111
 
3112
        if (detailed_status > I2O_DSC_INVALID_REQUEST)
3113
                printk(" / %0#4x.\n", detailed_status);
3114
        else
3115
                printk(" / %s.\n", LAN_DSC[detailed_status]);
3116
}
3117
 
3118
/*
3119
 * Used for error reporting/debugging purposes
3120
 */
3121
static void i2o_report_util_cmd(u8 cmd)
3122
{
3123
        switch (cmd) {
3124
        case I2O_CMD_UTIL_NOP:
3125
                printk("UTIL_NOP, ");
3126
                break;
3127
        case I2O_CMD_UTIL_ABORT:
3128
                printk("UTIL_ABORT, ");
3129
                break;
3130
        case I2O_CMD_UTIL_CLAIM:
3131
                printk("UTIL_CLAIM, ");
3132
                break;
3133
        case I2O_CMD_UTIL_RELEASE:
3134
                printk("UTIL_CLAIM_RELEASE, ");
3135
                break;
3136
        case I2O_CMD_UTIL_CONFIG_DIALOG:
3137
                printk("UTIL_CONFIG_DIALOG, ");
3138
                break;
3139
        case I2O_CMD_UTIL_DEVICE_RESERVE:
3140
                printk("UTIL_DEVICE_RESERVE, ");
3141
                break;
3142
        case I2O_CMD_UTIL_DEVICE_RELEASE:
3143
                printk("UTIL_DEVICE_RELEASE, ");
3144
                break;
3145
        case I2O_CMD_UTIL_EVT_ACK:
3146
                printk("UTIL_EVENT_ACKNOWLEDGE, ");
3147
                break;
3148
        case I2O_CMD_UTIL_EVT_REGISTER:
3149
                printk("UTIL_EVENT_REGISTER, ");
3150
                break;
3151
        case I2O_CMD_UTIL_LOCK:
3152
                printk("UTIL_LOCK, ");
3153
                break;
3154
        case I2O_CMD_UTIL_LOCK_RELEASE:
3155
                printk("UTIL_LOCK_RELEASE, ");
3156
                break;
3157
        case I2O_CMD_UTIL_PARAMS_GET:
3158
                printk("UTIL_PARAMS_GET, ");
3159
                break;
3160
        case I2O_CMD_UTIL_PARAMS_SET:
3161
                printk("UTIL_PARAMS_SET, ");
3162
                break;
3163
        case I2O_CMD_UTIL_REPLY_FAULT_NOTIFY:
3164
                printk("UTIL_REPLY_FAULT_NOTIFY, ");
3165
                break;
3166
        default:
3167
                printk("Cmd = %0#2x, ",cmd);
3168
        }
3169
}
3170
 
3171
/*
3172
 * Used for error reporting/debugging purposes
3173
 */
3174
static void i2o_report_exec_cmd(u8 cmd)
3175
{
3176
        switch (cmd) {
3177
        case I2O_CMD_ADAPTER_ASSIGN:
3178
                printk("EXEC_ADAPTER_ASSIGN, ");
3179
                break;
3180
        case I2O_CMD_ADAPTER_READ:
3181
                printk("EXEC_ADAPTER_READ, ");
3182
                break;
3183
        case I2O_CMD_ADAPTER_RELEASE:
3184
                printk("EXEC_ADAPTER_RELEASE, ");
3185
                break;
3186
        case I2O_CMD_BIOS_INFO_SET:
3187
                printk("EXEC_BIOS_INFO_SET, ");
3188
                break;
3189
        case I2O_CMD_BOOT_DEVICE_SET:
3190
                printk("EXEC_BOOT_DEVICE_SET, ");
3191
                break;
3192
        case I2O_CMD_CONFIG_VALIDATE:
3193
                printk("EXEC_CONFIG_VALIDATE, ");
3194
                break;
3195
        case I2O_CMD_CONN_SETUP:
3196
                printk("EXEC_CONN_SETUP, ");
3197
                break;
3198
        case I2O_CMD_DDM_DESTROY:
3199
                printk("EXEC_DDM_DESTROY, ");
3200
                break;
3201
        case I2O_CMD_DDM_ENABLE:
3202
                printk("EXEC_DDM_ENABLE, ");
3203
                break;
3204
        case I2O_CMD_DDM_QUIESCE:
3205
                printk("EXEC_DDM_QUIESCE, ");
3206
                break;
3207
        case I2O_CMD_DDM_RESET:
3208
                printk("EXEC_DDM_RESET, ");
3209
                break;
3210
        case I2O_CMD_DDM_SUSPEND:
3211
                printk("EXEC_DDM_SUSPEND, ");
3212
                break;
3213
        case I2O_CMD_DEVICE_ASSIGN:
3214
                printk("EXEC_DEVICE_ASSIGN, ");
3215
                break;
3216
        case I2O_CMD_DEVICE_RELEASE:
3217
                printk("EXEC_DEVICE_RELEASE, ");
3218
                break;
3219
        case I2O_CMD_HRT_GET:
3220
                printk("EXEC_HRT_GET, ");
3221
                break;
3222
        case I2O_CMD_ADAPTER_CLEAR:
3223
                printk("EXEC_IOP_CLEAR, ");
3224
                break;
3225
        case I2O_CMD_ADAPTER_CONNECT:
3226
                printk("EXEC_IOP_CONNECT, ");
3227
                break;
3228
        case I2O_CMD_ADAPTER_RESET:
3229
                printk("EXEC_IOP_RESET, ");
3230
                break;
3231
        case I2O_CMD_LCT_NOTIFY:
3232
                printk("EXEC_LCT_NOTIFY, ");
3233
                break;
3234
        case I2O_CMD_OUTBOUND_INIT:
3235
                printk("EXEC_OUTBOUND_INIT, ");
3236
                break;
3237
        case I2O_CMD_PATH_ENABLE:
3238
                printk("EXEC_PATH_ENABLE, ");
3239
                break;
3240
        case I2O_CMD_PATH_QUIESCE:
3241
                printk("EXEC_PATH_QUIESCE, ");
3242
                break;
3243
        case I2O_CMD_PATH_RESET:
3244
                printk("EXEC_PATH_RESET, ");
3245
                break;
3246
        case I2O_CMD_STATIC_MF_CREATE:
3247
                printk("EXEC_STATIC_MF_CREATE, ");
3248
                break;
3249
        case I2O_CMD_STATIC_MF_RELEASE:
3250
                printk("EXEC_STATIC_MF_RELEASE, ");
3251
                break;
3252
        case I2O_CMD_STATUS_GET:
3253
                printk("EXEC_STATUS_GET, ");
3254
                break;
3255
        case I2O_CMD_SW_DOWNLOAD:
3256
                printk("EXEC_SW_DOWNLOAD, ");
3257
                break;
3258
        case I2O_CMD_SW_UPLOAD:
3259
                printk("EXEC_SW_UPLOAD, ");
3260
                break;
3261
        case I2O_CMD_SW_REMOVE:
3262
                printk("EXEC_SW_REMOVE, ");
3263
                break;
3264
        case I2O_CMD_SYS_ENABLE:
3265
                printk("EXEC_SYS_ENABLE, ");
3266
                break;
3267
        case I2O_CMD_SYS_MODIFY:
3268
                printk("EXEC_SYS_MODIFY, ");
3269
                break;
3270
        case I2O_CMD_SYS_QUIESCE:
3271
                printk("EXEC_SYS_QUIESCE, ");
3272
                break;
3273
        case I2O_CMD_SYS_TAB_SET:
3274
                printk("EXEC_SYS_TAB_SET, ");
3275
                break;
3276
        default:
3277
                printk("Cmd = %#02x, ",cmd);
3278
        }
3279
}
3280
 
3281
/*
3282
 * Used for error reporting/debugging purposes
3283
 */
3284
static void i2o_report_lan_cmd(u8 cmd)
3285
{
3286
        switch (cmd) {
3287
        case LAN_PACKET_SEND:
3288
                printk("LAN_PACKET_SEND, ");
3289
                break;
3290
        case LAN_SDU_SEND:
3291
                printk("LAN_SDU_SEND, ");
3292
                break;
3293
        case LAN_RECEIVE_POST:
3294
                printk("LAN_RECEIVE_POST, ");
3295
                break;
3296
        case LAN_RESET:
3297
                printk("LAN_RESET, ");
3298
                break;
3299
        case LAN_SUSPEND:
3300
                printk("LAN_SUSPEND, ");
3301
                break;
3302
        default:
3303
                printk("Cmd = %0#2x, ",cmd);
3304
        }
3305
}
3306
 
3307
/*
3308
 * Used for error reporting/debugging purposes.
3309
 * Report Cmd name, Request status, Detailed Status.
3310
 */
3311
void i2o_report_status(const char *severity, const char *str, u32 *msg)
3312
{
3313
        u8 cmd = (msg[1]>>24)&0xFF;
3314
        u8 req_status = (msg[4]>>24)&0xFF;
3315
        u16 detailed_status = msg[4]&0xFFFF;
3316
        struct i2o_handler *h = i2o_handlers[msg[2] & (MAX_I2O_MODULES-1)];
3317
 
3318
        printk("%s%s: ", severity, str);
3319
 
3320
        if (cmd < 0x1F)                         // Utility cmd
3321
                i2o_report_util_cmd(cmd);
3322
 
3323
        else if (cmd >= 0xA0 && cmd <= 0xEF)    // Executive cmd
3324
                i2o_report_exec_cmd(cmd);
3325
 
3326
        else if (h->class == I2O_CLASS_LAN && cmd >= 0x30 && cmd <= 0x3F)
3327
                i2o_report_lan_cmd(cmd);        // LAN cmd
3328
        else
3329
                printk("Cmd = %0#2x, ", cmd);   // Other cmds
3330
 
3331
        if (msg[0] & MSG_FAIL) {
3332
                i2o_report_fail_status(req_status, msg);
3333
                return;
3334
        }
3335
 
3336
        i2o_report_common_status(req_status);
3337
 
3338
        if (cmd < 0x1F || (cmd >= 0xA0 && cmd <= 0xEF))
3339
                i2o_report_common_dsc(detailed_status);
3340
        else if (h->class == I2O_CLASS_LAN && cmd >= 0x30 && cmd <= 0x3F)
3341
                i2o_report_lan_dsc(detailed_status);
3342
        else
3343
                printk(" / DetailedStatus = %0#4x.\n", detailed_status);
3344
}
3345
 
3346
/* Used to dump a message to syslog during debugging */
3347
void i2o_dump_message(u32 *msg)
3348
{
3349
#ifdef DRIVERDEBUG
3350
        int i;
3351
        printk(KERN_INFO "Dumping I2O message size %d @ %p\n",
3352
                msg[0]>>16&0xffff, msg);
3353
        for(i = 0; i < ((msg[0]>>16)&0xffff); i++)
3354
                printk(KERN_INFO "  msg[%d] = %0#10x\n", i, msg[i]);
3355
#endif
3356
}
3357
 
3358
/*
3359
 * I2O reboot/shutdown notification.
3360
 *
3361
 * - Call each OSM's reboot notifier (if one exists)
3362
 * - Quiesce each IOP in the system
3363
 *
3364
 * Each IOP has to be quiesced before we can ensure that the system
3365
 * can be properly shutdown as a transaction that has already been
3366
 * acknowledged still needs to be placed in permanent store on the IOP.
3367
 * The SysQuiesce causes the IOP to force all HDMs to complete their
3368
 * transactions before returning, so only at that point is it safe
3369
 *
3370
 */
3371
static int i2o_reboot_event(struct notifier_block *n, unsigned long code, void
3372
*p)
3373
{
3374
        int i = 0;
3375
        struct i2o_controller *c = NULL;
3376
 
3377
        if(code != SYS_RESTART && code != SYS_HALT && code != SYS_POWER_OFF)
3378
                return NOTIFY_DONE;
3379
 
3380
        printk(KERN_INFO "Shutting down I2O system.\n");
3381
        printk(KERN_INFO
3382
                "   This could take a few minutes if there are many devices attached\n");
3383
 
3384
        for(i = 0; i < MAX_I2O_MODULES; i++)
3385
        {
3386
                if(i2o_handlers[i] && i2o_handlers[i]->reboot_notify)
3387
                        i2o_handlers[i]->reboot_notify();
3388
        }
3389
 
3390
        for(c = i2o_controller_chain; c; c = c->next)
3391
        {
3392
                if(i2o_quiesce_controller(c))
3393
                {
3394
                        printk(KERN_WARNING "i2o: Could not quiesce %s.\n"
3395
                               "Verify setup on next system power up.\n",
3396
                               c->name);
3397
                }
3398
        }
3399
 
3400
        printk(KERN_INFO "I2O system down.\n");
3401
        return NOTIFY_DONE;
3402
}
3403
 
3404
 
3405
EXPORT_SYMBOL(i2o_controller_chain);
3406
EXPORT_SYMBOL(i2o_num_controllers);
3407
EXPORT_SYMBOL(i2o_find_controller);
3408
EXPORT_SYMBOL(i2o_unlock_controller);
3409
EXPORT_SYMBOL(i2o_status_get);
3410
 
3411
EXPORT_SYMBOL(i2o_install_handler);
3412
EXPORT_SYMBOL(i2o_remove_handler);
3413
 
3414
EXPORT_SYMBOL(i2o_install_controller);
3415
EXPORT_SYMBOL(i2o_delete_controller);
3416
EXPORT_SYMBOL(i2o_run_queue);
3417
 
3418
EXPORT_SYMBOL(i2o_claim_device);
3419
EXPORT_SYMBOL(i2o_release_device);
3420
EXPORT_SYMBOL(i2o_device_notify_on);
3421
EXPORT_SYMBOL(i2o_device_notify_off);
3422
 
3423
EXPORT_SYMBOL(i2o_post_this);
3424
EXPORT_SYMBOL(i2o_post_wait);
3425
EXPORT_SYMBOL(i2o_post_wait_mem);
3426
 
3427
EXPORT_SYMBOL(i2o_query_scalar);
3428
EXPORT_SYMBOL(i2o_set_scalar);
3429
EXPORT_SYMBOL(i2o_query_table);
3430
EXPORT_SYMBOL(i2o_clear_table);
3431
EXPORT_SYMBOL(i2o_row_add_table);
3432
EXPORT_SYMBOL(i2o_issue_params);
3433
 
3434
EXPORT_SYMBOL(i2o_event_register);
3435
EXPORT_SYMBOL(i2o_event_ack);
3436
 
3437
EXPORT_SYMBOL(i2o_report_status);
3438
EXPORT_SYMBOL(i2o_dump_message);
3439
 
3440
EXPORT_SYMBOL(i2o_get_class_name);
3441
 
3442
EXPORT_SYMBOL_GPL(i2o_sys_init);
3443
 
3444
MODULE_AUTHOR("Red Hat Software");
3445
MODULE_DESCRIPTION("I2O Core");
3446
MODULE_LICENSE("GPL");
3447
 
3448
static int i2o_core_init(void)
3449
{
3450
        printk(KERN_INFO "I2O Core - (C) Copyright 1999 Red Hat Software\n");
3451
        if (i2o_install_handler(&i2o_core_handler) < 0)
3452
        {
3453
                printk(KERN_ERR "i2o_core: Unable to install core handler.\nI2O stack not loaded!");
3454
                return 0;
3455
        }
3456
 
3457
        core_context = i2o_core_handler.context;
3458
 
3459
        /*
3460
         * Initialize event handling thread
3461
         */
3462
 
3463
        init_MUTEX_LOCKED(&evt_sem);
3464
        evt_pid = kernel_thread(i2o_core_evt, &evt_reply, CLONE_SIGHAND);
3465
        if(evt_pid < 0)
3466
        {
3467
                printk(KERN_ERR "I2O: Could not create event handler kernel thread\n");
3468
                i2o_remove_handler(&i2o_core_handler);
3469
                return 0;
3470
        }
3471
        else
3472
                printk(KERN_INFO "I2O: Event thread created as pid %d\n", evt_pid);
3473
 
3474
        if(i2o_num_controllers)
3475
                i2o_sys_init();
3476
 
3477
        register_reboot_notifier(&i2o_reboot_notifier);
3478
 
3479
        return 0;
3480
}
3481
 
3482
static void i2o_core_exit(void)
3483
{
3484
        int stat;
3485
 
3486
        unregister_reboot_notifier(&i2o_reboot_notifier);
3487
 
3488
        if(i2o_num_controllers)
3489
                i2o_sys_shutdown();
3490
 
3491
        /*
3492
         * If this is shutdown time, the thread has already been killed
3493
         */
3494
        if(evt_running) {
3495
                printk("Terminating i2o threads...");
3496
                stat = kill_proc(evt_pid, SIGTERM, 1);
3497
                if(!stat) {
3498
                        printk("waiting...");
3499
                        wait_for_completion(&evt_dead);
3500
                }
3501
                printk("done.\n");
3502
        }
3503
        i2o_remove_handler(&i2o_core_handler);
3504
        unregister_reboot_notifier(&i2o_reboot_notifier);
3505
}
3506
 
3507
module_init(i2o_core_init);
3508
module_exit(i2o_core_exit);
3509
 

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