2 * Copyright (c) 2003,2004,2009 The DragonFly Project. All rights reserved.
4 * This code is derived from software contributed to The DragonFly Project
5 * by Matthew Dillon <dillon@backplane.com>
7 * Redistribution and use in source and binary forms, with or without
8 * modification, are permitted provided that the following conditions
11 * 1. Redistributions of source code must retain the above copyright
12 * notice, this list of conditions and the following disclaimer.
13 * 2. Redistributions in binary form must reproduce the above copyright
14 * notice, this list of conditions and the following disclaimer in
15 * the documentation and/or other materials provided with the
17 * 3. Neither the name of The DragonFly Project nor the names of its
18 * contributors may be used to endorse or promote products derived
19 * from this software without specific, prior written permission.
21 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
22 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
23 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
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29 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
30 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
31 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
34 * ----------------------------------------------------------------------------
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36 * <phk@FreeBSD.ORG> wrote this file. As long as you retain this notice you
37 * can do whatever you want with this stuff. If we meet some day, and you think
38 * this stuff is worth it, you can buy me a beer in return. Poul-Henning Kamp
39 * ----------------------------------------------------------------------------
41 * Copyright (c) 1982, 1986, 1988, 1993
42 * The Regents of the University of California. All rights reserved.
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44 * All or some portions of this file are derived from material licensed
45 * to the University of California by American Telephone and Telegraph
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47 * the permission of UNIX System Laboratories, Inc.
49 * Redistribution and use in source and binary forms, with or without
50 * modification, are permitted provided that the following conditions
52 * 1. Redistributions of source code must retain the above copyright
53 * notice, this list of conditions and the following disclaimer.
54 * 2. Redistributions in binary form must reproduce the above copyright
55 * notice, this list of conditions and the following disclaimer in the
56 * documentation and/or other materials provided with the distribution.
57 * 3. All advertising materials mentioning features or use of this software
58 * must display the following acknowledgement:
59 * This product includes software developed by the University of
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61 * 4. Neither the name of the University nor the names of its contributors
62 * may be used to endorse or promote products derived from this software
63 * without specific prior written permission.
65 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
66 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
67 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
68 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
69 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
70 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
71 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
72 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
73 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
74 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
77 * @(#)ufs_disksubr.c 8.5 (Berkeley) 1/21/94
78 * $FreeBSD: src/sys/kern/subr_disk.c,v 1.20.2.6 2001/10/05 07:14:57 peter Exp $
79 * $FreeBSD: src/sys/ufs/ufs/ufs_disksubr.c,v 1.44.2.3 2001/03/05 05:42:19 obrien Exp $
80 * $DragonFly: src/sys/kern/subr_disk.c,v 1.40 2008/06/05 18:06:32 swildner Exp $
83 #include <sys/param.h>
84 #include <sys/systm.h>
85 #include <sys/kernel.h>
87 #include <sys/sysctl.h>
90 #include <sys/disklabel.h>
91 #include <sys/disklabel32.h>
92 #include <sys/disklabel64.h>
93 #include <sys/diskslice.h>
94 #include <sys/diskmbr.h>
96 #include <sys/malloc.h>
97 #include <sys/sysctl.h>
98 #include <machine/md_var.h>
99 #include <sys/ctype.h>
100 #include <sys/syslog.h>
101 #include <sys/device.h>
102 #include <sys/msgport.h>
103 #include <sys/msgport2.h>
104 #include <sys/buf2.h>
105 #include <sys/devfs.h>
106 #include <sys/thread.h>
107 #include <sys/thread2.h>
109 #include <sys/queue.h>
110 #include <sys/lock.h>
112 static MALLOC_DEFINE(M_DISK
, "disk", "disk data");
113 static int disk_debug_enable
= 0;
115 static void disk_msg_autofree_reply(lwkt_port_t
, lwkt_msg_t
);
116 static void disk_msg_core(void *);
117 static int disk_probe_slice(struct disk
*dp
, cdev_t dev
, int slice
, int reprobe
);
118 static void disk_probe(struct disk
*dp
, int reprobe
);
119 static void _setdiskinfo(struct disk
*disk
, struct disk_info
*info
);
120 static void bioqwritereorder(struct bio_queue_head
*bioq
);
121 static void disk_cleanserial(char *serno
);
123 static d_open_t diskopen
;
124 static d_close_t diskclose
;
125 static d_ioctl_t diskioctl
;
126 static d_strategy_t diskstrategy
;
127 static d_psize_t diskpsize
;
128 static d_clone_t diskclone
;
129 static d_dump_t diskdump
;
131 static LIST_HEAD(, disk
) disklist
= LIST_HEAD_INITIALIZER(&disklist
);
132 static struct lwkt_token disklist_token
;
134 static struct dev_ops disk_ops
= {
135 { "disk", 0, D_DISK
},
137 .d_close
= diskclose
,
139 .d_write
= physwrite
,
140 .d_ioctl
= diskioctl
,
141 .d_strategy
= diskstrategy
,
143 .d_psize
= diskpsize
,
147 static struct objcache
*disk_msg_cache
;
149 struct objcache_malloc_args disk_msg_malloc_args
= {
150 sizeof(struct disk_msg
), M_DISK
};
152 static struct lwkt_port disk_dispose_port
;
153 static struct lwkt_port disk_msg_port
;
156 disk_debug(int level
, char *fmt
, ...)
161 if (level
<= disk_debug_enable
)
169 disk_probe_slice(struct disk
*dp
, cdev_t dev
, int slice
, int reprobe
)
171 struct disk_info
*info
= &dp
->d_info
;
172 struct diskslice
*sp
= &dp
->d_slice
->dss_slices
[slice
];
174 struct partinfo part
;
181 "disk_probe_slice (begin): %s (%s)\n",
182 dev
->si_name
, dp
->d_cdev
->si_name
);
184 sno
= slice
? slice
- 1 : 0;
186 ops
= &disklabel32_ops
;
187 msg
= ops
->op_readdisklabel(dev
, sp
, &sp
->ds_label
, info
);
188 if (msg
&& !strcmp(msg
, "no disk label")) {
189 ops
= &disklabel64_ops
;
190 msg
= ops
->op_readdisklabel(dev
, sp
, &sp
->ds_label
, info
);
193 if (slice
!= WHOLE_DISK_SLICE
)
194 ops
->op_adjust_label_reserved(dp
->d_slice
, slice
, sp
);
199 for (i
= 0; i
< ops
->op_getnumparts(sp
->ds_label
); i
++) {
200 ops
->op_loadpartinfo(sp
->ds_label
, i
, &part
);
203 (ndev
= devfs_find_device_by_name("%s%c",
204 dev
->si_name
, 'a' + i
))
207 * Device already exists and
210 ndev
->si_flags
|= SI_REPROBE_TEST
;
212 ndev
= make_dev_covering(&disk_ops
, dp
->d_rawdev
,
213 dkmakeminor(dkunit(dp
->d_cdev
),
215 UID_ROOT
, GID_OPERATOR
, 0640,
216 "%s%c", dev
->si_name
, 'a'+ i
);
218 if (dp
->d_info
.d_serialno
) {
221 dp
->d_info
.d_serialno
,
224 ndev
->si_flags
|= SI_REPROBE_TEST
;
228 } else if (info
->d_dsflags
& DSO_COMPATLABEL
) {
230 if (sp
->ds_size
>= 0x100000000ULL
)
231 ops
= &disklabel64_ops
;
233 ops
= &disklabel32_ops
;
234 sp
->ds_label
= ops
->op_clone_label(info
, sp
);
236 if (sp
->ds_type
== DOSPTYP_386BSD
/* XXX */) {
237 log(LOG_WARNING
, "%s: cannot find label (%s)\n",
243 sp
->ds_wlabel
= FALSE
;
246 return (msg
? EINVAL
: 0);
251 disk_probe(struct disk
*dp
, int reprobe
)
253 struct disk_info
*info
= &dp
->d_info
;
254 cdev_t dev
= dp
->d_cdev
;
257 struct diskslice
*sp
;
259 KKASSERT (info
->d_media_blksize
!= 0);
261 dp
->d_slice
= dsmakeslicestruct(BASE_SLICE
, info
);
263 "disk_probe (begin): %s\n",
264 dp
->d_cdev
->si_name
);
266 error
= mbrinit(dev
, info
, &(dp
->d_slice
));
270 for (i
= 0; i
< dp
->d_slice
->dss_nslices
; i
++) {
272 * Ignore the whole-disk slice, it has already been created.
274 if (i
== WHOLE_DISK_SLICE
)
276 sp
= &dp
->d_slice
->dss_slices
[i
];
279 * Handle s0. s0 is a compatibility slice if there are no
280 * other slices and it has not otherwise been set up, else
283 if (i
== COMPATIBILITY_SLICE
) {
285 if (sp
->ds_type
== 0 &&
286 dp
->d_slice
->dss_nslices
== BASE_SLICE
) {
287 sp
->ds_size
= info
->d_media_blocks
;
296 * Ignore 0-length slices
298 if (sp
->ds_size
== 0)
302 (ndev
= devfs_find_device_by_name("%ss%d",
303 dev
->si_name
, sno
))) {
305 * Device already exists and is still valid
307 ndev
->si_flags
|= SI_REPROBE_TEST
;
310 * Else create new device
312 ndev
= make_dev_covering(&disk_ops
, dp
->d_rawdev
,
313 dkmakewholeslice(dkunit(dev
), i
),
314 UID_ROOT
, GID_OPERATOR
, 0640,
315 "%ss%d", dev
->si_name
, sno
);
316 if (dp
->d_info
.d_serialno
) {
317 make_dev_alias(ndev
, "serno/%s.s%d",
318 dp
->d_info
.d_serialno
, sno
);
321 ndev
->si_flags
|= SI_REPROBE_TEST
;
326 * Probe appropriate slices for a disklabel
328 * XXX slice type 1 used by our gpt probe code.
329 * XXX slice type 0 used by mbr compat slice.
331 if (sp
->ds_type
== DOSPTYP_386BSD
|| sp
->ds_type
== 0 ||
333 if (dp
->d_slice
->dss_first_bsd_slice
== 0)
334 dp
->d_slice
->dss_first_bsd_slice
= i
;
335 disk_probe_slice(dp
, ndev
, i
, reprobe
);
339 "disk_probe (end): %s\n",
340 dp
->d_cdev
->si_name
);
345 disk_msg_core(void *arg
)
348 struct diskslice
*sp
;
353 lwkt_initport_thread(&disk_msg_port
, curthread
);
358 msg
= (disk_msg_t
)lwkt_waitport(&disk_msg_port
, 0);
360 switch (msg
->hdr
.u
.ms_result
) {
361 case DISK_DISK_PROBE
:
362 dp
= (struct disk
*)msg
->load
;
364 "DISK_DISK_PROBE: %s\n",
365 dp
->d_cdev
->si_name
);
368 case DISK_DISK_DESTROY
:
369 dp
= (struct disk
*)msg
->load
;
371 "DISK_DISK_DESTROY: %s\n",
372 dp
->d_cdev
->si_name
);
373 devfs_destroy_subnames(dp
->d_cdev
->si_name
);
374 devfs_destroy_dev(dp
->d_cdev
);
375 lwkt_gettoken(&ilock
, &disklist_token
);
376 LIST_REMOVE(dp
, d_list
);
377 lwkt_reltoken(&ilock
);
378 if (dp
->d_info
.d_serialno
) {
379 kfree(dp
->d_info
.d_serialno
, M_TEMP
);
380 dp
->d_info
.d_serialno
= NULL
;
384 dp
= (struct disk
*)msg
->load
;
386 "DISK_DISK_UNPROBE: %s\n",
387 dp
->d_cdev
->si_name
);
388 devfs_destroy_subnames(dp
->d_cdev
->si_name
);
390 case DISK_SLICE_REPROBE
:
391 dp
= (struct disk
*)msg
->load
;
392 sp
= (struct diskslice
*)msg
->load2
;
393 devfs_clr_subnames_flag(sp
->ds_dev
->si_name
,
396 "DISK_SLICE_REPROBE: %s\n",
397 sp
->ds_dev
->si_name
);
398 disk_probe_slice(dp
, sp
->ds_dev
,
399 dkslice(sp
->ds_dev
), 1);
400 devfs_destroy_subnames_without_flag(
401 sp
->ds_dev
->si_name
, SI_REPROBE_TEST
);
403 case DISK_DISK_REPROBE
:
404 dp
= (struct disk
*)msg
->load
;
405 devfs_clr_subnames_flag(dp
->d_cdev
->si_name
, SI_REPROBE_TEST
);
407 "DISK_DISK_REPROBE: %s\n",
408 dp
->d_cdev
->si_name
);
410 devfs_destroy_subnames_without_flag(
411 dp
->d_cdev
->si_name
, SI_REPROBE_TEST
);
414 disk_debug(1, "DISK_SYNC\n");
417 devfs_debug(DEVFS_DEBUG_WARNING
,
418 "disk_msg_core: unknown message "
419 "received at core\n");
422 lwkt_replymsg((lwkt_msg_t
)msg
, 0);
429 * Acts as a message drain. Any message that is replied to here gets
430 * destroyed and the memory freed.
433 disk_msg_autofree_reply(lwkt_port_t port
, lwkt_msg_t msg
)
435 objcache_put(disk_msg_cache
, msg
);
440 disk_msg_send(uint32_t cmd
, void *load
, void *load2
)
443 lwkt_port_t port
= &disk_msg_port
;
445 disk_msg
= objcache_get(disk_msg_cache
, M_WAITOK
);
447 lwkt_initmsg(&disk_msg
->hdr
, &disk_dispose_port
, 0);
449 disk_msg
->hdr
.u
.ms_result
= cmd
;
450 disk_msg
->load
= load
;
451 disk_msg
->load2
= load2
;
453 lwkt_sendmsg(port
, (lwkt_msg_t
)disk_msg
);
457 disk_msg_send_sync(uint32_t cmd
, void *load
, void *load2
)
459 struct lwkt_port rep_port
;
460 disk_msg_t disk_msg
= objcache_get(disk_msg_cache
, M_WAITOK
);
461 disk_msg_t msg_incoming
;
462 lwkt_port_t port
= &disk_msg_port
;
464 lwkt_initport_thread(&rep_port
, curthread
);
465 lwkt_initmsg(&disk_msg
->hdr
, &rep_port
, 0);
467 disk_msg
->hdr
.u
.ms_result
= cmd
;
468 disk_msg
->load
= load
;
469 disk_msg
->load2
= load2
;
472 lwkt_sendmsg(port
, (lwkt_msg_t
)disk_msg
);
473 msg_incoming
= lwkt_waitport(&rep_port
, 0);
477 * Create a raw device for the dev_ops template (which is returned). Also
478 * create a slice and unit managed disk and overload the user visible
479 * device space with it.
481 * NOTE: The returned raw device is NOT a slice and unit managed device.
482 * It is an actual raw device representing the raw disk as specified by
483 * the passed dev_ops. The disk layer not only returns such a raw device,
484 * it also uses it internally when passing (modified) commands through.
487 disk_create(int unit
, struct disk
*dp
, struct dev_ops
*raw_ops
)
493 "disk_create (begin): %s%d\n",
494 raw_ops
->head
.name
, unit
);
496 rawdev
= make_only_dev(raw_ops
, dkmakewholedisk(unit
),
497 UID_ROOT
, GID_OPERATOR
, 0640,
498 "%s%d", raw_ops
->head
.name
, unit
);
500 bzero(dp
, sizeof(*dp
));
502 dp
->d_rawdev
= rawdev
;
503 dp
->d_raw_ops
= raw_ops
;
504 dp
->d_dev_ops
= &disk_ops
;
505 dp
->d_cdev
= make_dev_covering(&disk_ops
, dp
->d_rawdev
,
506 dkmakewholedisk(unit
),
507 UID_ROOT
, GID_OPERATOR
, 0640,
508 "%s%d", raw_ops
->head
.name
, unit
);
510 dp
->d_cdev
->si_disk
= dp
;
512 lwkt_gettoken(&ilock
, &disklist_token
);
513 LIST_INSERT_HEAD(&disklist
, dp
, d_list
);
514 lwkt_reltoken(&ilock
);
517 "disk_create (end): %s%d\n",
518 raw_ops
->head
.name
, unit
);
520 return (dp
->d_rawdev
);
525 _setdiskinfo(struct disk
*disk
, struct disk_info
*info
)
529 oldserialno
= disk
->d_info
.d_serialno
;
530 bcopy(info
, &disk
->d_info
, sizeof(disk
->d_info
));
531 info
= &disk
->d_info
;
534 "_setdiskinfo: %s\n",
535 disk
->d_cdev
->si_name
);
538 * The serial number is duplicated so the caller can throw
541 if (info
->d_serialno
&& info
->d_serialno
[0]) {
542 info
->d_serialno
= kstrdup(info
->d_serialno
, M_TEMP
);
543 disk_cleanserial(info
->d_serialno
);
545 make_dev_alias(disk
->d_cdev
, "serno/%s",
549 info
->d_serialno
= NULL
;
552 kfree(oldserialno
, M_TEMP
);
555 * The caller may set d_media_size or d_media_blocks and we
556 * calculate the other.
558 KKASSERT(info
->d_media_size
== 0 || info
->d_media_blksize
== 0);
559 if (info
->d_media_size
== 0 && info
->d_media_blocks
) {
560 info
->d_media_size
= (u_int64_t
)info
->d_media_blocks
*
561 info
->d_media_blksize
;
562 } else if (info
->d_media_size
&& info
->d_media_blocks
== 0 &&
563 info
->d_media_blksize
) {
564 info
->d_media_blocks
= info
->d_media_size
/
565 info
->d_media_blksize
;
569 * The si_* fields for rawdev are not set until after the
570 * disk_create() call, so someone using the cooked version
571 * of the raw device (i.e. da0s0) will not get the right
572 * si_iosize_max unless we fix it up here.
574 if (disk
->d_cdev
&& disk
->d_rawdev
&&
575 disk
->d_cdev
->si_iosize_max
== 0) {
576 disk
->d_cdev
->si_iosize_max
= disk
->d_rawdev
->si_iosize_max
;
577 disk
->d_cdev
->si_bsize_phys
= disk
->d_rawdev
->si_bsize_phys
;
578 disk
->d_cdev
->si_bsize_best
= disk
->d_rawdev
->si_bsize_best
;
583 * Disk drivers must call this routine when media parameters are available
587 disk_setdiskinfo(struct disk
*disk
, struct disk_info
*info
)
589 _setdiskinfo(disk
, info
);
590 disk_msg_send(DISK_DISK_PROBE
, disk
, NULL
);
592 "disk_setdiskinfo: sent probe for %s\n",
593 disk
->d_cdev
->si_name
);
597 disk_setdiskinfo_sync(struct disk
*disk
, struct disk_info
*info
)
599 _setdiskinfo(disk
, info
);
600 disk_msg_send_sync(DISK_DISK_PROBE
, disk
, NULL
);
602 "disk_setdiskinfo_sync: sent probe for %s\n",
603 disk
->d_cdev
->si_name
);
607 * This routine is called when an adapter detaches. The higher level
608 * managed disk device is destroyed while the lower level raw device is
612 disk_destroy(struct disk
*disk
)
614 disk_msg_send_sync(DISK_DISK_DESTROY
, disk
, NULL
);
619 disk_dumpcheck(cdev_t dev
, u_int64_t
*count
, u_int64_t
*blkno
, u_int
*secsize
)
621 struct partinfo pinfo
;
624 bzero(&pinfo
, sizeof(pinfo
));
625 error
= dev_dioctl(dev
, DIOCGPART
, (void *)&pinfo
, 0,
626 proc0
.p_ucred
, NULL
);
629 if (pinfo
.media_blksize
== 0)
631 *count
= (u_int64_t
)Maxmem
* PAGE_SIZE
/ pinfo
.media_blksize
;
632 if (dumplo64
< pinfo
.reserved_blocks
||
633 dumplo64
+ *count
> pinfo
.media_blocks
) {
636 *blkno
= dumplo64
+ pinfo
.media_offset
/ pinfo
.media_blksize
;
637 *secsize
= pinfo
.media_blksize
;
642 disk_unprobe(struct disk
*disk
)
647 disk_msg_send_sync(DISK_UNPROBE
, disk
, NULL
);
651 disk_invalidate (struct disk
*disk
)
654 dsgone(&disk
->d_slice
);
658 disk_enumerate(struct disk
*disk
)
663 lwkt_gettoken(&ilock
, &disklist_token
);
665 dp
= (LIST_FIRST(&disklist
));
667 dp
= (LIST_NEXT(disk
, d_list
));
668 lwkt_reltoken(&ilock
);
675 sysctl_disks(SYSCTL_HANDLER_ARGS
)
683 while ((disk
= disk_enumerate(disk
))) {
685 error
= SYSCTL_OUT(req
, " ", 1);
691 error
= SYSCTL_OUT(req
, disk
->d_rawdev
->si_name
,
692 strlen(disk
->d_rawdev
->si_name
));
696 error
= SYSCTL_OUT(req
, "", 1);
700 SYSCTL_PROC(_kern
, OID_AUTO
, disks
, CTLTYPE_STRING
| CTLFLAG_RD
, NULL
, 0,
701 sysctl_disks
, "A", "names of available disks");
704 * Open a disk device or partition.
708 diskopen(struct dev_open_args
*ap
)
710 cdev_t dev
= ap
->a_head
.a_dev
;
715 * dp can't be NULL here XXX.
717 * d_slice will be NULL if setdiskinfo() has not been called yet.
718 * setdiskinfo() is typically called whether the disk is present
719 * or not (e.g. CD), but the base disk device is created first
720 * and there may be a race.
723 if (dp
== NULL
|| dp
->d_slice
== NULL
)
728 * Deal with open races
730 while (dp
->d_flags
& DISKFLAG_LOCK
) {
731 dp
->d_flags
|= DISKFLAG_WANTED
;
732 error
= tsleep(dp
, PCATCH
, "diskopen", hz
);
736 dp
->d_flags
|= DISKFLAG_LOCK
;
739 * Open the underlying raw device.
741 if (!dsisopen(dp
->d_slice
)) {
743 if (!pdev
->si_iosize_max
)
744 pdev
->si_iosize_max
= dev
->si_iosize_max
;
746 error
= dev_dopen(dp
->d_rawdev
, ap
->a_oflags
,
747 ap
->a_devtype
, ap
->a_cred
);
751 * Inherit properties from the underlying device now that it is
759 error
= dsopen(dev
, ap
->a_devtype
, dp
->d_info
.d_dsflags
,
760 &dp
->d_slice
, &dp
->d_info
);
761 if (!dsisopen(dp
->d_slice
)) {
762 dev_dclose(dp
->d_rawdev
, ap
->a_oflags
, ap
->a_devtype
);
765 dp
->d_flags
&= ~DISKFLAG_LOCK
;
766 if (dp
->d_flags
& DISKFLAG_WANTED
) {
767 dp
->d_flags
&= ~DISKFLAG_WANTED
;
775 * Close a disk device or partition
779 diskclose(struct dev_close_args
*ap
)
781 cdev_t dev
= ap
->a_head
.a_dev
;
788 dsclose(dev
, ap
->a_devtype
, dp
->d_slice
);
789 if (!dsisopen(dp
->d_slice
)) {
790 error
= dev_dclose(dp
->d_rawdev
, ap
->a_fflag
, ap
->a_devtype
);
796 * First execute the ioctl on the disk device, and if it isn't supported
797 * try running it on the backing device.
801 diskioctl(struct dev_ioctl_args
*ap
)
803 cdev_t dev
= ap
->a_head
.a_dev
;
811 devfs_debug(DEVFS_DEBUG_DEBUG
,
812 "diskioctl: cmd is: %x (name: %s)\n",
813 ap
->a_cmd
, dev
->si_name
);
814 devfs_debug(DEVFS_DEBUG_DEBUG
,
815 "diskioctl: &dp->d_slice is: %x, %x\n",
816 &dp
->d_slice
, dp
->d_slice
);
818 error
= dsioctl(dev
, ap
->a_cmd
, ap
->a_data
, ap
->a_fflag
,
819 &dp
->d_slice
, &dp
->d_info
);
821 if (error
== ENOIOCTL
) {
822 error
= dev_dioctl(dp
->d_rawdev
, ap
->a_cmd
, ap
->a_data
,
823 ap
->a_fflag
, ap
->a_cred
, NULL
);
829 * Execute strategy routine
833 diskstrategy(struct dev_strategy_args
*ap
)
835 cdev_t dev
= ap
->a_head
.a_dev
;
836 struct bio
*bio
= ap
->a_bio
;
843 bio
->bio_buf
->b_error
= ENXIO
;
844 bio
->bio_buf
->b_flags
|= B_ERROR
;
848 KKASSERT(dev
->si_disk
== dp
);
851 * The dscheck() function will also transform the slice relative
852 * block number i.e. bio->bio_offset into a block number that can be
853 * passed directly to the underlying raw device. If dscheck()
854 * returns NULL it will have handled the bio for us (e.g. EOF
855 * or error due to being beyond the device size).
857 if ((nbio
= dscheck(dev
, bio
, dp
->d_slice
)) != NULL
) {
858 dev_dstrategy(dp
->d_rawdev
, nbio
);
866 * Return the partition size in ?blocks?
870 diskpsize(struct dev_psize_args
*ap
)
872 cdev_t dev
= ap
->a_head
.a_dev
;
878 ap
->a_result
= dssize(dev
, &dp
->d_slice
);
883 * When new device entries are instantiated, make sure they inherit our
884 * si_disk structure and block and iosize limits from the raw device.
886 * This routine is always called synchronously in the context of the
889 * XXX The various io and block size constraints are not always initialized
890 * properly by devices.
894 diskclone(struct dev_clone_args
*ap
)
896 cdev_t dev
= ap
->a_head
.a_dev
;
900 KKASSERT(dp
!= NULL
);
902 dev
->si_iosize_max
= dp
->d_rawdev
->si_iosize_max
;
903 dev
->si_bsize_phys
= dp
->d_rawdev
->si_bsize_phys
;
904 dev
->si_bsize_best
= dp
->d_rawdev
->si_bsize_best
;
909 diskdump(struct dev_dump_args
*ap
)
911 cdev_t dev
= ap
->a_head
.a_dev
;
912 struct disk
*dp
= dev
->si_disk
;
915 error
= disk_dumpcheck(dev
, &ap
->a_count
, &ap
->a_blkno
, &ap
->a_secsize
);
917 ap
->a_head
.a_dev
= dp
->d_rawdev
;
918 error
= dev_doperate(&ap
->a_head
);
925 SYSCTL_INT(_debug_sizeof
, OID_AUTO
, diskslices
, CTLFLAG_RD
,
926 0, sizeof(struct diskslices
), "sizeof(struct diskslices)");
928 SYSCTL_INT(_debug_sizeof
, OID_AUTO
, disk
, CTLFLAG_RD
,
929 0, sizeof(struct disk
), "sizeof(struct disk)");
932 * Reorder interval for burst write allowance and minor write
935 * We always want to trickle some writes in to make use of the
936 * disk's zone cache. Bursting occurs on a longer interval and only
937 * runningbufspace is well over the hirunningspace limit.
939 int bioq_reorder_burst_interval
= 60; /* should be multiple of minor */
940 SYSCTL_INT(_kern
, OID_AUTO
, bioq_reorder_burst_interval
,
941 CTLFLAG_RW
, &bioq_reorder_burst_interval
, 0, "");
942 int bioq_reorder_minor_interval
= 5;
943 SYSCTL_INT(_kern
, OID_AUTO
, bioq_reorder_minor_interval
,
944 CTLFLAG_RW
, &bioq_reorder_minor_interval
, 0, "");
946 int bioq_reorder_burst_bytes
= 3000000;
947 SYSCTL_INT(_kern
, OID_AUTO
, bioq_reorder_burst_bytes
,
948 CTLFLAG_RW
, &bioq_reorder_burst_bytes
, 0, "");
949 int bioq_reorder_minor_bytes
= 262144;
950 SYSCTL_INT(_kern
, OID_AUTO
, bioq_reorder_minor_bytes
,
951 CTLFLAG_RW
, &bioq_reorder_minor_bytes
, 0, "");
955 * Order I/Os. Generally speaking this code is designed to make better
956 * use of drive zone caches. A drive zone cache can typically track linear
957 * reads or writes for around 16 zones simultaniously.
959 * Read prioritization issues: It is possible for hundreds of megabytes worth
960 * of writes to be queued asynchronously. This creates a huge bottleneck
961 * for reads which reduce read bandwidth to a trickle.
963 * To solve this problem we generally reorder reads before writes.
965 * However, a large number of random reads can also starve writes and
966 * make poor use of the drive zone cache so we allow writes to trickle
970 bioqdisksort(struct bio_queue_head
*bioq
, struct bio
*bio
)
973 * The BIO wants to be ordered. Adding to the tail also
974 * causes transition to be set to NULL, forcing the ordering
975 * of all prior I/O's.
977 if (bio
->bio_buf
->b_flags
& B_ORDERED
) {
978 bioq_insert_tail(bioq
, bio
);
982 switch(bio
->bio_buf
->b_cmd
) {
984 if (bioq
->transition
) {
986 * Insert before the first write. Bleedover writes
987 * based on reorder intervals to prevent starvation.
989 TAILQ_INSERT_BEFORE(bioq
->transition
, bio
, bio_act
);
991 if (bioq
->reorder
% bioq_reorder_minor_interval
== 0) {
992 bioqwritereorder(bioq
);
994 bioq_reorder_burst_interval
) {
1000 * No writes queued (or ordering was forced),
1003 TAILQ_INSERT_TAIL(&bioq
->queue
, bio
, bio_act
);
1008 * Writes are always appended. If no writes were previously
1009 * queued or an ordered tail insertion occured the transition
1010 * field will be NULL.
1012 TAILQ_INSERT_TAIL(&bioq
->queue
, bio
, bio_act
);
1013 if (bioq
->transition
== NULL
)
1014 bioq
->transition
= bio
;
1018 * All other request types are forced to be ordered.
1020 bioq_insert_tail(bioq
, bio
);
1026 * Move the read-write transition point to prevent reads from
1027 * completely starving our writes. This brings a number of writes into
1028 * the fold every N reads.
1030 * We bring a few linear writes into the fold on a minor interval
1031 * and we bring a non-linear burst of writes into the fold on a major
1032 * interval. Bursting only occurs if runningbufspace is really high
1033 * (typically from syncs, fsyncs, or HAMMER flushes).
1037 bioqwritereorder(struct bio_queue_head
*bioq
)
1045 if (bioq
->reorder
< bioq_reorder_burst_interval
||
1046 !buf_runningbufspace_severe()) {
1047 left
= (size_t)bioq_reorder_minor_bytes
;
1050 left
= (size_t)bioq_reorder_burst_bytes
;
1054 next_offset
= bioq
->transition
->bio_offset
;
1055 while ((bio
= bioq
->transition
) != NULL
&&
1056 (check_off
== 0 || next_offset
== bio
->bio_offset
)
1058 n
= bio
->bio_buf
->b_bcount
;
1059 next_offset
= bio
->bio_offset
+ n
;
1060 bioq
->transition
= TAILQ_NEXT(bio
, bio_act
);
1068 * Disk error is the preface to plaintive error messages
1069 * about failing disk transfers. It prints messages of the form
1071 hp0g: hard error reading fsbn 12345 of 12344-12347 (hp0 bn %d cn %d tn %d sn %d)
1073 * if the offset of the error in the transfer and a disk label
1074 * are both available. blkdone should be -1 if the position of the error
1075 * is unknown; the disklabel pointer may be null from drivers that have not
1076 * been converted to use them. The message is printed with kprintf
1077 * if pri is LOG_PRINTF, otherwise it uses log at the specified priority.
1078 * The message should be completed (with at least a newline) with kprintf
1079 * or log(-1, ...), respectively. There is no trailing space.
1082 diskerr(struct bio
*bio
, cdev_t dev
, const char *what
, int pri
, int donecnt
)
1084 struct buf
*bp
= bio
->bio_buf
;
1098 kprintf("%s: %s %sing ", dev
->si_name
, what
, term
);
1099 kprintf("offset %012llx for %d",
1100 (long long)bio
->bio_offset
,
1104 kprintf(" (%d bytes completed)", donecnt
);
1108 * Locate a disk device
1111 disk_locate(const char *devname
)
1113 return devfs_find_device_by_name(devname
);
1117 disk_config(void *arg
)
1119 disk_msg_send_sync(DISK_SYNC
, NULL
, NULL
);
1125 struct thread
* td_core
;
1127 disk_msg_cache
= objcache_create("disk-msg-cache", 0, 0,
1129 objcache_malloc_alloc
,
1130 objcache_malloc_free
,
1131 &disk_msg_malloc_args
);
1133 lwkt_token_init(&disklist_token
);
1136 * Initialize the reply-only port which acts as a message drain
1138 lwkt_initport_replyonly(&disk_dispose_port
, disk_msg_autofree_reply
);
1140 lwkt_create(disk_msg_core
, /*args*/NULL
, &td_core
, NULL
,
1141 0, 0, "disk_msg_core");
1143 tsleep(td_core
, 0, "diskcore", 0);
1149 objcache_destroy(disk_msg_cache
);
1153 * Clean out illegal characters in serial numbers.
1156 disk_cleanserial(char *serno
)
1160 while ((c
= *serno
) != 0) {
1161 if (c
>= 'a' && c
<= 'z')
1163 else if (c
>= 'A' && c
<= 'Z')
1165 else if (c
>= '0' && c
<= '9')
1167 else if (c
== '-' || c
== '@' || c
== '+' || c
== '.')
1175 TUNABLE_INT("kern.disk_debug", &disk_debug_enable
);
1176 SYSCTL_INT(_kern
, OID_AUTO
, disk_debug
, CTLFLAG_RW
, &disk_debug_enable
,
1177 0, "Enable subr_disk debugging");
1179 SYSINIT(disk_register
, SI_SUB_PRE_DRIVERS
, SI_ORDER_FIRST
, disk_init
, NULL
);
1180 SYSUNINIT(disk_register
, SI_SUB_PRE_DRIVERS
, SI_ORDER_ANY
, disk_uninit
, NULL
);