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/*
md.c : Multiple Devices driver for Linux
Copyright (C) 1994-96 Marc ZYNGIER
<zyngier@ufr-info-p7.ibp.fr> or
<maz@gloups.fdn.fr>
A lot of inspiration came from hd.c ...
kerneld support by Boris Tobotras <boris@xtalk.msk.su>
boot support for linear and striped mode by Harald Hoyer <HarryH@Royal.Net>
RAID-1/RAID-5 extensions by:
Ingo Molnar, Miguel de Icaza, Gadi Oxman
Changes for kmod by:
Cyrus Durgin
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2, or (at your option)
any later version.
You should have received a copy of the GNU General Public License
(for example /usr/src/linux/COPYING); if not, write to the Free
Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
/*
* Current RAID-1,4,5 parallel reconstruction speed limit is 1024 KB/sec, so
* the extra system load does not show up that much. Increase it if your
* system can take more.
*/
#define SPEED_LIMIT 1024
#include <linux/config.h>
#include <linux/module.h>
#include <linux/version.h>
#include <linux/malloc.h>
#include <linux/mm.h>
#include <linux/md.h>
#include <linux/hdreg.h>
#include <linux/stat.h>
#include <linux/fs.h>
#include <linux/proc_fs.h>
#include <linux/blkdev.h>
#include <linux/genhd.h>
#include <linux/smp_lock.h>
#ifdef CONFIG_KMOD
#include <linux/kmod.h>
#endif
#include <linux/errno.h>
#include <linux/init.h>
#define __KERNEL_SYSCALLS__
#include <linux/unistd.h>
#define MAJOR_NR MD_MAJOR
#define MD_DRIVER
#include <linux/blk.h>
#include <asm/uaccess.h>
#include <asm/bitops.h>
#include <asm/atomic.h>
#ifdef CONFIG_MD_BOOT
extern kdev_t name_to_kdev_t(char *line) __init;
#endif
static struct hd_struct md_hd_struct[MAX_MD_DEV];
static int md_blocksizes[MAX_MD_DEV];
int md_maxreadahead[MAX_MD_DEV];
static struct md_thread md_threads[MAX_MD_THREADS];
#if SUPPORT_RECONSTRUCTION
static struct md_thread *md_sync_thread = NULL;
#endif /* SUPPORT_RECONSTRUCTION */
int md_size[MAX_MD_DEV]={0, };
static void md_geninit (struct gendisk *);
static struct gendisk md_gendisk=
{
MD_MAJOR,
"md",
0,
1,
MAX_MD_DEV,
md_geninit,
md_hd_struct,
md_size,
MAX_MD_DEV,
NULL,
NULL
};
static struct md_personality *pers[MAX_PERSONALITY]={NULL, };
struct md_dev md_dev[MAX_MD_DEV];
static struct gendisk *find_gendisk (kdev_t dev)
{
struct gendisk *tmp=gendisk_head;
while (tmp != NULL)
{
if (tmp->major==MAJOR(dev))
return (tmp);
tmp=tmp->next;
}
return (NULL);
}
char *partition_name (kdev_t dev)
{
static char name[40]; /* This should be long
enough for a device name ! */
struct gendisk *hd = find_gendisk (dev);
if (!hd)
{
sprintf (name, "[dev %s]", kdevname(dev));
return (name);
}
return disk_name (hd, MINOR(dev), name); /* routine in genhd.c */
}
static int legacy_raid_sb (int minor, int pnum)
{
int i, factor;
factor = 1 << FACTOR_SHIFT(FACTOR((md_dev+minor)));
/*****
* do size and offset calculations.
*/
for (i=0; i<md_dev[minor].nb_dev; i++) {
md_dev[minor].devices[i].size &= ~(factor - 1);
md_size[minor] += md_dev[minor].devices[i].size;
md_dev[minor].devices[i].offset=i ? (md_dev[minor].devices[i-1].offset +
md_dev[minor].devices[i-1].size) : 0;
}
if (pnum == RAID0 >> PERSONALITY_SHIFT)
md_maxreadahead[minor] = MD_DEFAULT_DISK_READAHEAD * md_dev[minor].nb_dev;
return 0;
}
static void free_sb (struct md_dev *mddev)
{
int i;
struct real_dev *realdev;
if (mddev->sb) {
free_page((unsigned long) mddev->sb);
mddev->sb = NULL;
}
for (i = 0; i <mddev->nb_dev; i++) {
realdev = mddev->devices + i;
if (realdev->sb) {
free_page((unsigned long) realdev->sb);
realdev->sb = NULL;
}
}
}
/*
* Check one RAID superblock for generic plausibility
*/
#define BAD_MAGIC KERN_ERR \
"md: %s: invalid raid superblock magic (%x) on block %u\n"
#define OUT_OF_MEM KERN_ALERT \
"md: out of memory.\n"
#define NO_DEVICE KERN_ERR \
"md: disabled device %s\n"
#define SUCCESS 0
#define FAILURE -1
static int analyze_one_sb (struct real_dev * rdev)
{
int ret = FAILURE;
struct buffer_head *bh;
kdev_t dev = rdev->dev;
md_superblock_t *sb;
/*
* Read the superblock, it's at the end of the disk
*/
rdev->sb_offset = MD_NEW_SIZE_BLOCKS (blk_size[MAJOR(dev)][MINOR(dev)]);
set_blocksize (dev, MD_SB_BYTES);
bh = bread (dev, rdev->sb_offset / MD_SB_BLOCKS, MD_SB_BYTES);
if (bh) {
sb = (md_superblock_t *) bh->b_data;
if (sb->md_magic != MD_SB_MAGIC) {
printk (BAD_MAGIC, kdevname(dev),
sb->md_magic, rdev->sb_offset);
goto abort;
}
rdev->sb = (md_superblock_t *) __get_free_page(GFP_KERNEL);
if (!rdev->sb) {
printk (OUT_OF_MEM);
goto abort;
}
memcpy (rdev->sb, bh->b_data, MD_SB_BYTES);
rdev->size = sb->size;
} else
printk (NO_DEVICE,kdevname(rdev->dev));
ret = SUCCESS;
abort:
if (bh)
brelse (bh);
return ret;
}
#undef SUCCESS
#undef FAILURE
#undef BAD_MAGIC
#undef OUT_OF_MEM
#undef NO_DEVICE
/*
* Check a full RAID array for plausibility
*/
#define INCONSISTENT KERN_ERR \
"md: superblock inconsistency -- run ckraid\n"
#define OUT_OF_DATE KERN_ERR \
"md: superblock update time inconsistenty -- using the most recent one\n"
#define OLD_VERSION KERN_ALERT \
"md: %s: unsupported raid array version %d.%d.%d\n"
#define NOT_CLEAN KERN_ERR \
"md: %s: raid array is not clean -- run ckraid\n"
#define NOT_CLEAN_IGNORE KERN_ERR \
"md: %s: raid array is not clean -- reconstructing parity\n"
#define UNKNOWN_LEVEL KERN_ERR \
"md: %s: unsupported raid level %d\n"
static int analyze_sbs (int minor, int pnum)
{
struct md_dev *mddev = md_dev + minor;
int i, N = mddev->nb_dev, out_of_date = 0;
struct real_dev * disks = mddev->devices;
md_superblock_t *sb, *freshest = NULL;
/*
* RAID-0 and linear don't use a RAID superblock
*/
if (pnum == RAID0 >> PERSONALITY_SHIFT ||
pnum == LINEAR >> PERSONALITY_SHIFT)
return legacy_raid_sb (minor, pnum);
/*
* Verify the RAID superblock on each real device
*/
for (i = 0; i < N; i++)
if (analyze_one_sb(disks+i))
goto abort;
/*
* The superblock constant part has to be the same
* for all disks in the array.
*/
sb = NULL;
for (i = 0; i < N; i++) {
if (!disks[i].sb)
continue;
if (!sb) {
sb = disks[i].sb;
continue;
}
if (memcmp(sb,
disks[i].sb, MD_SB_GENERIC_CONSTANT_WORDS * 4)) {
printk (INCONSISTENT);
goto abort;
}
}
/*
* Ok, we have all disks and the array is ready to run. Lets
* find the freshest superblock, that one will be the superblock
* that represents the whole array.
*/
if ((sb = mddev->sb = (md_superblock_t *) __get_free_page (GFP_KERNEL)) == NULL)
goto abort;
freshest = NULL;
for (i = 0; i < N; i++) {
if (!disks[i].sb)
continue;
if (!freshest) {
freshest = disks[i].sb;
continue;
}
/*
* Find the newest superblock version
*/
if (disks[i].sb->utime != freshest->utime) {
out_of_date = 1;
if (disks[i].sb->utime > freshest->utime)
freshest = disks[i].sb;
}
}
if (out_of_date)
printk(OUT_OF_DATE);
memcpy (sb, freshest, sizeof(*freshest));
/*
* Check if we can support this RAID array
*/
if (sb->major_version != MD_MAJOR_VERSION ||
sb->minor_version > MD_MINOR_VERSION) {
printk (OLD_VERSION, kdevname(MKDEV(MD_MAJOR, minor)),
sb->major_version, sb->minor_version,
sb->patch_version);
goto abort;
}
/*
* We need to add this as a superblock option.
*/
#if SUPPORT_RECONSTRUCTION
if (sb->state != (1 << MD_SB_CLEAN)) {
if (sb->level == 1) {
printk (NOT_CLEAN, kdevname(MKDEV(MD_MAJOR, minor)));
goto abort;
} else
printk (NOT_CLEAN_IGNORE, kdevname(MKDEV(MD_MAJOR, minor)));
}
#else
if (sb->state != (1 << MD_SB_CLEAN)) {
printk (NOT_CLEAN, kdevname(MKDEV(MD_MAJOR, minor)));
goto abort;
}
#endif /* SUPPORT_RECONSTRUCTION */
switch (sb->level) {
case 1:
md_size[minor] = sb->size;
md_maxreadahead[minor] = MD_DEFAULT_DISK_READAHEAD;
break;
case 4:
case 5:
md_size[minor] = sb->size * (sb->raid_disks - 1);
md_maxreadahead[minor] = MD_DEFAULT_DISK_READAHEAD * (sb->raid_disks - 1);
break;
default:
printk (UNKNOWN_LEVEL, kdevname(MKDEV(MD_MAJOR, minor)),
sb->level);
goto abort;
}
return 0;
abort:
free_sb(mddev);
return 1;
}
#undef INCONSISTENT
#undef OUT_OF_DATE
#undef OLD_VERSION
#undef NOT_CLEAN
#undef OLD_LEVEL
int md_update_sb(int minor)
{
struct md_dev *mddev = md_dev + minor;
struct buffer_head *bh;
md_superblock_t *sb = mddev->sb;
struct real_dev *realdev;
kdev_t dev;
int i;
u32 sb_offset;
sb->utime = CURRENT_TIME;
for (i = 0; i < mddev->nb_dev; i++) {
realdev = mddev->devices + i;
if (!realdev->sb)
continue;
dev = realdev->dev;
sb_offset = realdev->sb_offset;
set_blocksize(dev, MD_SB_BYTES);
printk("md: updating raid superblock on device %s, sb_offset == %u\n", kdevname(dev), sb_offset);
bh = getblk(dev, sb_offset / MD_SB_BLOCKS, MD_SB_BYTES);
if (bh) {
sb = (md_superblock_t *) bh->b_data;
memcpy(sb, mddev->sb, MD_SB_BYTES);
memcpy(&sb->descriptor, sb->disks + realdev->sb->descriptor.number, MD_SB_DESCRIPTOR_WORDS * 4);
mark_buffer_uptodate(bh, 1);
mark_buffer_dirty(bh, 1);
ll_rw_block(WRITE, 1, &bh);
wait_on_buffer(bh);
bforget(bh);
fsync_dev(dev);
invalidate_buffers(dev);
} else
printk(KERN_ERR "md: getblk failed for device %s\n", kdevname(dev));
}
return 0;
}
static int do_md_run (int minor, int repart)
{
int pnum, i, min, factor, err;
if (!md_dev[minor].nb_dev)
return -EINVAL;
if (md_dev[minor].pers)
return -EBUSY;
md_dev[minor].repartition=repart;
if ((pnum=PERSONALITY(&md_dev[minor]) >> (PERSONALITY_SHIFT))
>= MAX_PERSONALITY)
return -EINVAL;
/* Only RAID-1 and RAID-5 can have MD devices as underlying devices */
if (pnum != (RAID1 >> PERSONALITY_SHIFT) && pnum != (RAID5 >> PERSONALITY_SHIFT)){
for (i = 0; i < md_dev [minor].nb_dev; i++)
if (MAJOR (md_dev [minor].devices [i].dev) == MD_MAJOR)
return -EINVAL;
}
if (!pers[pnum])
{
#ifdef CONFIG_KMOD
char module_name[80];
sprintf (module_name, "md-personality-%d", pnum);
request_module (module_name);
if (!pers[pnum])
#endif
return -EINVAL;
}
factor = min = 1 << FACTOR_SHIFT(FACTOR((md_dev+minor)));
for (i=0; i<md_dev[minor].nb_dev; i++)
if (md_dev[minor].devices[i].size<min)
{
printk ("Dev %s smaller than %dk, cannot shrink\n",
partition_name (md_dev[minor].devices[i].dev), min);
return -EINVAL;
}
for (i=0; i<md_dev[minor].nb_dev; i++) {
fsync_dev(md_dev[minor].devices[i].dev);
invalidate_buffers(md_dev[minor].devices[i].dev);
}
/* Resize devices according to the factor. It is used to align
partitions size on a given chunk size. */
md_size[minor]=0;
/*
* Analyze the raid superblock
*/
if (analyze_sbs(minor, pnum))
return -EINVAL;
md_dev[minor].pers=pers[pnum];
if ((err=md_dev[minor].pers->run (minor, md_dev+minor)))
{
md_dev[minor].pers=NULL;
free_sb(md_dev + minor);
return (err);
}
if (pnum != RAID0 >> PERSONALITY_SHIFT && pnum != LINEAR >> PERSONALITY_SHIFT)
{
md_dev[minor].sb->state &= ~(1 << MD_SB_CLEAN);
md_update_sb(minor);
}
/* FIXME : We assume here we have blocks
that are twice as large as sectors.
THIS MAY NOT BE TRUE !!! */
md_hd_struct[minor].start_sect=0;
md_hd_struct[minor].nr_sects=md_size[minor]<<1;
read_ahead[MD_MAJOR] = 128;
return (0);
}
static int do_md_stop (int minor, struct inode *inode)
{
int i;
if (inode->i_count>1 || md_dev[minor].busy>1) {
/*
* ioctl : one open channel
*/
printk ("STOP_MD md%x failed : i_count=%d, busy=%d\n",
minor, inode->i_count, md_dev[minor].busy);
return -EBUSY;
}
if (md_dev[minor].pers) {
/*
* It is safe to call stop here, it only frees private
* data. Also, it tells us if a device is unstoppable
* (eg. resyncing is in progress)
*/
if (md_dev[minor].pers->stop (minor, md_dev+minor))
return -EBUSY;
/*
* The device won't exist anymore -> flush it now
*/
fsync_dev (inode->i_rdev);
invalidate_buffers (inode->i_rdev);
if (md_dev[minor].sb) {
md_dev[minor].sb->state |= 1 << MD_SB_CLEAN;
md_update_sb(minor);
}
}
/* Remove locks. */
if (md_dev[minor].sb)
free_sb(md_dev + minor);
for (i=0; i<md_dev[minor].nb_dev; i++)
clear_inode (md_dev[minor].devices[i].inode);
md_dev[minor].nb_dev=md_size[minor]=0;
md_hd_struct[minor].nr_sects=0;
md_dev[minor].pers=NULL;
read_ahead[MD_MAJOR] = 128;
return (0);
}
static int do_md_add (int minor, kdev_t dev)
{
int i;
int hot_add=0;
struct real_dev *realdev;
if (md_dev[minor].nb_dev==MAX_REAL)
return -EINVAL;
if (!fs_may_mount (dev))
return -EBUSY;
if (blk_size[MAJOR(dev)] == NULL || blk_size[MAJOR(dev)][MINOR(dev)] == 0) {
printk("md_add(): zero device size, huh, bailing out.\n");
return -EINVAL;
}
if (md_dev[minor].pers) {
/*
* The array is already running, hot-add the drive, or
* bail out:
*/
if (!md_dev[minor].pers->hot_add_disk)
return -EBUSY;
else
hot_add=1;
}
/*
* Careful. We cannot increase nb_dev for a running array.
*/
i=md_dev[minor].nb_dev;
realdev = &md_dev[minor].devices[i];
realdev->dev=dev;
/* Lock the device by inserting a dummy inode. This doesn't
smell very good, but I need to be consistent with the
mount stuff, specially with fs_may_mount. If someone have
a better idea, please help ! */
realdev->inode=get_empty_inode ();
realdev->inode->i_dev=dev; /* don't care about other fields */
insert_inode_hash (realdev->inode);
/* Sizes are now rounded at run time */
/* md_dev[minor].devices[i].size=gen_real->sizes[MINOR(dev)]; HACKHACK*/
realdev->size=blk_size[MAJOR(dev)][MINOR(dev)];
if (hot_add) {
/*
* Check the superblock for consistency.
* the personality itself has to check wether it's getting
* added with the proper flags ... also, personality has to
* be checked too ;)
*/
if (analyze_one_sb (realdev))
return -EINVAL;
/*
* hot_add has to bump up nb_dev itself
*/
if (md_dev[minor].pers->hot_add_disk (&md_dev[minor], dev)) {
/*
* FIXME: here we should free up the inode and stuff
*/
printk ("FIXME\n");
return -EINVAL;
}
} else
md_dev[minor].nb_dev++;
printk ("REGISTER_DEV %s to md%x done\n", partition_name(dev), minor);
return (0);
}
static int md_ioctl (struct inode *inode, struct file *file,
unsigned int cmd, unsigned long arg)
{
int minor, err;
struct hd_geometry *loc = (struct hd_geometry *) arg;
if (!suser())
return -EACCES;
if (((minor=MINOR(inode->i_rdev)) & 0x80) &&
(minor & 0x7f) < MAX_PERSONALITY &&
pers[minor & 0x7f] &&
pers[minor & 0x7f]->ioctl)
return (pers[minor & 0x7f]->ioctl (inode, file, cmd, arg));
if (minor >= MAX_MD_DEV)
return -EINVAL;
switch (cmd)
{
case REGISTER_DEV:
return do_md_add (minor, to_kdev_t ((dev_t) arg));
case START_MD:
return do_md_run (minor, (int) arg);
case STOP_MD:
return do_md_stop (minor, inode);
case BLKGETSIZE: /* Return device size */
if (!arg) return -EINVAL;
err = put_user (md_hd_struct[MINOR(inode->i_rdev)].nr_sects, (long *) arg);
if (err)
return err;
break;
case BLKFLSBUF:
fsync_dev (inode->i_rdev);
invalidate_buffers (inode->i_rdev);
break;
case BLKRASET:
if (arg > 0xff)
return -EINVAL;
read_ahead[MAJOR(inode->i_rdev)] = arg;
return 0;
case BLKRAGET:
if (!arg) return -EINVAL;
err = put_user (read_ahead[MAJOR(inode->i_rdev)], (long *) arg);
if (err)
return err;
break;
/* We have a problem here : there is no easy way to give a CHS
virtual geometry. We currently pretend that we have a 2 heads
4 sectors (with a BIG number of cylinders...). This drives dosfs
just mad... ;-) */
case HDIO_GETGEO:
if (!loc) return -EINVAL;
err = put_user (2, (char *) &loc->heads);
if (err)
return err;
err = put_user (4, (char *) &loc->sectors);
if (err)
return err;
err = put_user (md_hd_struct[minor].nr_sects/8, (short *) &loc->cylinders);
if (err)
return err;
err = put_user (md_hd_struct[MINOR(inode->i_rdev)].start_sect,
(long *) &loc->start);
if (err)
return err;
break;
RO_IOCTLS(inode->i_rdev,arg);
default:
printk ("Unknown md_ioctl %d\n", cmd);
return -EINVAL;
}
return (0);
}
static int md_open (struct inode *inode, struct file *file)
{
int minor=MINOR(inode->i_rdev);
md_dev[minor].busy++;
return (0); /* Always succeed */
}
static int md_release (struct inode *inode, struct file *file)
{
int minor=MINOR(inode->i_rdev);
sync_dev (inode->i_rdev);
md_dev[minor].busy--;
return 0;
}
static ssize_t md_read (struct file *file, char *buf, size_t count,
loff_t *ppos)
{
int minor=MINOR(file->f_dentry->d_inode->i_rdev);
if (!md_dev[minor].pers) /* Check if device is being run */
return -ENXIO;
return block_read(file, buf, count, ppos);
}
static ssize_t md_write (struct file *file, const char *buf,
size_t count, loff_t *ppos)
{
int minor=MINOR(file->f_dentry->d_inode->i_rdev);
if (!md_dev[minor].pers) /* Check if device is being run */
return -ENXIO;
return block_write(file, buf, count, ppos);
}
static struct file_operations md_fops=
{
NULL,
md_read,
md_write,
NULL,
NULL,
md_ioctl,
NULL,
md_open,
md_release,
block_fsync
};
int md_map (int minor, kdev_t *rdev, unsigned long *rsector, unsigned long size)
{
if ((unsigned int) minor >= MAX_MD_DEV)
{
printk ("Bad md device %d\n", minor);
return (-1);
}
if (!md_dev[minor].pers)
{
printk ("Oops ! md%d not running, giving up !\n", minor);
return (-1);
}
return (md_dev[minor].pers->map(md_dev+minor, rdev, rsector, size));
}
int md_make_request (int minor, int rw, struct buffer_head * bh)
{
if (md_dev [minor].pers->make_request) {
if (buffer_locked(bh))
return 0;
set_bit(BH_Lock, &bh->b_state);
if (rw == WRITE || rw == WRITEA) {
if (!buffer_dirty(bh)) {
bh->b_end_io(bh, test_bit(BH_Uptodate, &bh->b_state));
return 0;
}
}
if (rw == READ || rw == READA) {
if (buffer_uptodate(bh)) {
bh->b_end_io(bh, test_bit(BH_Uptodate, &bh->b_state));
return 0;
}
}
return (md_dev[minor].pers->make_request(md_dev+minor, rw, bh));
} else {
make_request (MAJOR(bh->b_rdev), rw, bh);
return 0;
}
}
static void do_md_request (void)
{
printk ("Got md request, not good...");
return;
}
/*
* We run MAX_MD_THREADS from md_init() and arbitrate them in run time.
* This is not so elegant, but how can we use kernel_thread() from within
* loadable modules?
*/
struct md_thread *md_register_thread (void (*run) (void *), void *data)
{
int i;
for (i = 0; i < MAX_MD_THREADS; i++) {
if (md_threads[i].run == NULL) {
md_threads[i].run = run;
md_threads[i].data = data;
return md_threads + i;
}
}
return NULL;
}
void md_unregister_thread (struct md_thread *thread)
{
thread->run = NULL;
thread->data = NULL;
thread->flags = 0;
}
void md_wakeup_thread(struct md_thread *thread)
{
set_bit(THREAD_WAKEUP, &thread->flags);
wake_up(&thread->wqueue);
}
EXPORT_SYMBOL(md_size);
EXPORT_SYMBOL(md_maxreadahead);
EXPORT_SYMBOL(register_md_personality);
EXPORT_SYMBOL(unregister_md_personality);
EXPORT_SYMBOL(partition_name);
EXPORT_SYMBOL(md_dev);
EXPORT_SYMBOL(md_error);
EXPORT_SYMBOL(md_register_thread);
EXPORT_SYMBOL(md_unregister_thread);
EXPORT_SYMBOL(md_update_sb);
EXPORT_SYMBOL(md_map);
EXPORT_SYMBOL(md_wakeup_thread);
EXPORT_SYMBOL(md_do_sync);
static struct proc_dir_entry proc_md = {
PROC_MD, 6, "mdstat",
S_IFREG | S_IRUGO, 1, 0, 0,
0, &proc_array_inode_operations,
};
static void md_geninit (struct gendisk *gdisk)
{
int i;
for(i=0;i<MAX_MD_DEV;i++)
{
md_blocksizes[i] = 1024;
md_maxreadahead[i] = MD_DEFAULT_DISK_READAHEAD;
md_gendisk.part[i].start_sect=-1; /* avoid partition check */
md_gendisk.part[i].nr_sects=0;
md_dev[i].pers=NULL;
}
blksize_size[MD_MAJOR] = md_blocksizes;
max_readahead[MD_MAJOR] = md_maxreadahead;
proc_register(&proc_root, &proc_md);
}
int md_error (kdev_t mddev, kdev_t rdev)
{
unsigned int minor = MINOR (mddev);
int rc;
if (MAJOR(mddev) != MD_MAJOR || minor > MAX_MD_DEV)
panic ("md_error gets unknown device\n");
if (!md_dev [minor].pers)
panic ("md_error gets an error for an unknown device\n");
if (md_dev [minor].pers->error_handler) {
rc = md_dev [minor].pers->error_handler (md_dev+minor, rdev);
#if SUPPORT_RECONSTRUCTION
md_wakeup_thread(md_sync_thread);
#endif /* SUPPORT_RECONSTRUCTION */
return rc;
}
return 0;
}
int get_md_status (char *page)
{
int sz=0, i, j, size;
sz+=sprintf( page+sz, "Personalities : ");
for (i=0; i<MAX_PERSONALITY; i++)
if (pers[i])
sz+=sprintf (page+sz, "[%d %s] ", i, pers[i]->name);
page[sz-1]='\n';
sz+=sprintf (page+sz, "read_ahead ");
if (read_ahead[MD_MAJOR]==INT_MAX)
sz+=sprintf (page+sz, "not set\n");
else
sz+=sprintf (page+sz, "%d sectors\n", read_ahead[MD_MAJOR]);
for (i=0; i<MAX_MD_DEV; i++)
{
sz+=sprintf (page+sz, "md%d : %sactive", i, md_dev[i].pers ? "" : "in");
if (md_dev[i].pers)
sz+=sprintf (page+sz, " %s", md_dev[i].pers->name);
size=0;
for (j=0; j<md_dev[i].nb_dev; j++)
{
sz+=sprintf (page+sz, " %s",
partition_name(md_dev[i].devices[j].dev));
size+=md_dev[i].devices[j].size;
}
if (md_dev[i].nb_dev) {
if (md_dev[i].pers)
sz+=sprintf (page+sz, " %d blocks", md_size[i]);
else
sz+=sprintf (page+sz, " %d blocks", size);
}
if (!md_dev[i].pers)
{
sz+=sprintf (page+sz, "\n");
continue;
}
if (md_dev[i].pers->max_invalid_dev)
sz+=sprintf (page+sz, " maxfault=%ld", MAX_FAULT(md_dev+i));
sz+=md_dev[i].pers->status (page+sz, i, md_dev+i);
sz+=sprintf (page+sz, "\n");
}
return (sz);
}
int register_md_personality (int p_num, struct md_personality *p)
{
int i=(p_num >> PERSONALITY_SHIFT);
if (i >= MAX_PERSONALITY)
return -EINVAL;
if (pers[i])
return -EBUSY;
pers[i]=p;
printk ("%s personality registered\n", p->name);
return 0;
}
int unregister_md_personality (int p_num)
{
int i=(p_num >> PERSONALITY_SHIFT);
if (i >= MAX_PERSONALITY)
return -EINVAL;
printk ("%s personality unregistered\n", pers[i]->name);
pers[i]=NULL;
return 0;
}
int md_thread(void * arg)
{
struct md_thread *thread = arg;
current->session = 1;
current->pgrp = 1;
sprintf(current->comm, "md_thread");
lock_kernel();
for (;;) {
sti();
clear_bit(THREAD_WAKEUP, &thread->flags);
if (thread->run) {
thread->run(thread->data);
run_task_queue(&tq_disk);
}
cli();
if (!test_bit(THREAD_WAKEUP, &thread->flags)) {
do {
spin_lock(¤t->sigmask_lock);
flush_signals(current);
spin_unlock(¤t->sigmask_lock);
interruptible_sleep_on(&thread->wqueue);
cli();
if (test_bit(THREAD_WAKEUP, &thread->flags))
break;
} while (signal_pending(current));
}
}
}
static md_descriptor_t *get_spare(struct md_dev *mddev)
{
int i;
md_superblock_t *sb = mddev->sb;
md_descriptor_t *descriptor;
struct real_dev *realdev;
for (i = 0; i < mddev->nb_dev; i++) {
realdev = &mddev->devices[i];
if (!realdev->sb)
continue;
descriptor = &sb->disks[realdev->sb->descriptor.number];
if (descriptor->state & (1 << MD_FAULTY_DEVICE))
continue;
if (descriptor->state & (1 << MD_ACTIVE_DEVICE))
continue;
return descriptor;
}
return NULL;
}
/*
* parallel resyncing thread.
*
* FIXME: - make it abort with a dirty array on mdstop, now it just blocks
* - fix read error handing
*/
int md_do_sync(struct md_dev *mddev)
{
struct buffer_head *bh;
int max_blocks, blocksize, curr_bsize, percent=1, j;
kdev_t read_disk = MKDEV(MD_MAJOR, mddev - md_dev);
int major = MAJOR(read_disk), minor = MINOR(read_disk);
unsigned long starttime;
blocksize = blksize_size[major][minor];
max_blocks = blk_size[major][minor] / (blocksize >> 10);
printk("... resync log\n");
printk(" .... mddev->nb_dev: %d\n", mddev->nb_dev);
printk(" .... raid array: %s\n", kdevname(read_disk));
printk(" .... max_blocks: %d blocksize: %d\n", max_blocks, blocksize);
printk("md: syncing RAID array %s\n", kdevname(read_disk));
mddev->busy++;
starttime=jiffies;
for (j = 0; j < max_blocks; j++) {
/*
* B careful. When some1 mounts a non-'blocksize' filesystem
* then we get the blocksize changed right under us. Go deal
* with it transparently, recalculate 'blocksize', 'j' and
* 'max_blocks':
*/
curr_bsize = blksize_size[major][minor];
if (curr_bsize != blocksize) {
diff_blocksize:
if (curr_bsize > blocksize)
/*
* this is safe, rounds downwards.
*/
j /= curr_bsize/blocksize;
else
j *= blocksize/curr_bsize;
blocksize = curr_bsize;
max_blocks = blk_size[major][minor] / (blocksize >> 10);
}
if ((bh = breada (read_disk, j, blocksize, j * blocksize,
max_blocks * blocksize)) != NULL) {
mark_buffer_dirty(bh, 1);
brelse(bh);
} else {
/*
* FIXME: Ugly, but set_blocksize() isnt safe ...
*/
curr_bsize = blksize_size[major][minor];
if (curr_bsize != blocksize)
goto diff_blocksize;
/*
* It's a real read problem. FIXME, handle this
* a better way.
*/
printk ( KERN_ALERT
"read error, stopping reconstruction.\n");
mddev->busy--;
return 1;
}
/*
* Lets sleep some if we are faster than our speed limit:
*/
while (blocksize*j/(jiffies-starttime+1)*HZ/1024 > SPEED_LIMIT)
{
current->state = TASK_INTERRUPTIBLE;
current->timeout = jiffies+1;
schedule();
}
/*
* FIXME: put this status bar thing into /proc
*/
if (!(j%(max_blocks/100))) {
if (!(percent%10))
printk (" %03d%% done.\n",percent);
else
printk (".");
percent++;
}
}
fsync_dev(read_disk);
printk("md: %s: sync done.\n", kdevname(read_disk));
mddev->busy--;
return 0;
}
/*
* This is a kernel thread which: syncs a spare disk with the active array
*
* the amount of foolproofing might seem to be a tad excessive, but an
* early (not so error-safe) version of raid1syncd synced the first 0.5 gigs
* of my root partition with the first 0.5 gigs of my /home partition ... so
* i'm a bit nervous ;)
*/
void mdsyncd (void *data)
{
int i;
struct md_dev *mddev;
md_superblock_t *sb;
md_descriptor_t *spare;
unsigned long flags;
for (i = 0, mddev = md_dev; i < MAX_MD_DEV; i++, mddev++) {
if ((sb = mddev->sb) == NULL)
continue;
if (sb->active_disks == sb->raid_disks)
continue;
if (!sb->spare_disks)
continue;
if ((spare = get_spare(mddev)) == NULL)
continue;
if (!mddev->pers->mark_spare)
continue;
if (mddev->pers->mark_spare(mddev, spare, SPARE_WRITE))
continue;
if (md_do_sync(mddev) || (spare->state & (1 << MD_FAULTY_DEVICE))) {
mddev->pers->mark_spare(mddev, spare, SPARE_INACTIVE);
continue;
}
save_flags(flags);
cli();
mddev->pers->mark_spare(mddev, spare, SPARE_ACTIVE);
spare->state |= (1 << MD_SYNC_DEVICE);
spare->state |= (1 << MD_ACTIVE_DEVICE);
sb->spare_disks--;
sb->active_disks++;
mddev->sb_dirty = 1;
md_update_sb(mddev - md_dev);
restore_flags(flags);
}
}
#ifdef CONFIG_MD_BOOT
struct {
int set;
int ints[100];
char str[100];
} md_setup_args __initdata = {
0,{0},{0}
};
/* called from init/main.c */
__initfunc(void md_setup(char *str,int *ints))
{
int i;
for(i=0;i<=ints[0];i++) {
md_setup_args.ints[i] = ints[i];
strcpy(md_setup_args.str, str);
/* printk ("md: ints[%d]=%d.\n", i, ints[i]);*/
}
md_setup_args.set=1;
return;
}
__initfunc(void do_md_setup(char *str,int *ints))
{
int minor, pers, factor, fault;
kdev_t dev;
int i=1;
if(ints[0] < 4) {
printk ("md: Too few Arguments (%d).\n", ints[0]);
return;
}
minor=ints[i++];
if (minor >= MAX_MD_DEV) {
printk ("md: Minor device number too high.\n");
return;
}
pers = 0;
switch(ints[i++]) { /* Raidlevel */
case -1:
#ifdef CONFIG_MD_LINEAR
pers = LINEAR;
printk ("md: Setting up md%d as linear device.\n",minor);
#else
printk ("md: Linear mode not configured."
"Recompile the kernel with linear mode enabled!\n");
#endif
break;
case 0:
pers = STRIPED;
#ifdef CONFIG_MD_STRIPED
printk ("md: Setting up md%d as a striped device.\n",minor);
#else
printk ("md: Striped mode not configured."
"Recompile the kernel with striped mode enabled!\n");
#endif
break;
/* not supported yet
case 1:
pers = RAID1;
printk ("md: Setting up md%d as a raid1 device.\n",minor);
break;
case 5:
pers = RAID5;
printk ("md: Setting up md%d as a raid5 device.\n",minor);
break;
*/
default:
printk ("md: Unknown or not supported raid level %d.\n", ints[--i]);
return;
}
if(pers) {
factor=ints[i++]; /* Chunksize */
fault =ints[i++]; /* Faultlevel */
pers=pers | factor | (fault << FAULT_SHIFT);
while( str && (dev = name_to_kdev_t(str))) {
do_md_add (minor, dev);
if((str = strchr (str, ',')) != NULL)
str++;
}
do_md_run (minor, pers);
printk ("md: Loading md%d.\n",minor);
}
}
#endif
void linear_init (void);
void raid0_init (void);
void raid1_init (void);
void raid5_init (void);
__initfunc(int md_init (void))
{
int i;
printk ("md driver %d.%d.%d MAX_MD_DEV=%d, MAX_REAL=%d\n",
MD_MAJOR_VERSION, MD_MINOR_VERSION, MD_PATCHLEVEL_VERSION,
MAX_MD_DEV, MAX_REAL);
if (register_blkdev (MD_MAJOR, "md", &md_fops))
{
printk ("Unable to get major %d for md\n", MD_MAJOR);
return (-1);
}
memset(md_threads, 0, MAX_MD_THREADS * sizeof(struct md_thread));
printk("md: starting %d kernel threads\n", MAX_MD_THREADS);
for (i = 0; i < MAX_MD_THREADS; i++) {
md_threads[i].run = NULL;
init_waitqueue(&md_threads[i].wqueue);
md_threads[i].flags = 0;
kernel_thread (md_thread, md_threads + i, 0);
}
blk_dev[MD_MAJOR].request_fn=DEVICE_REQUEST;
blk_dev[MD_MAJOR].current_request=NULL;
read_ahead[MD_MAJOR]=INT_MAX;
memset(md_dev, 0, MAX_MD_DEV * sizeof (struct md_dev));
md_gendisk.next=gendisk_head;
gendisk_head=&md_gendisk;
#if SUPPORT_RECONSTRUCTION
if ((md_sync_thread = md_register_thread(mdsyncd, NULL)) == NULL)
printk("md: bug: md_sync_thread == NULL\n");
#endif /* SUPPORT_RECONSTRUCTION */
#ifdef CONFIG_MD_LINEAR
linear_init ();
#endif
#ifdef CONFIG_MD_STRIPED
raid0_init ();
#endif
#ifdef CONFIG_MD_MIRRORING
raid1_init ();
#endif
#ifdef CONFIG_MD_RAID5
raid5_init ();
#endif
return (0);
}
#ifdef CONFIG_MD_BOOT
__initfunc(void md_setup_drive(void))
{
if(md_setup_args.set)
do_md_setup(md_setup_args.str, md_setup_args.ints);
}
#endif
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