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/* File growth and truncation
Copyright (C) 1993, 1994, 1995 Free Software Foundation
This file is part of the GNU Hurd.
The GNU Hurd 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.
The GNU Hurd is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with the GNU Hurd; see the file COPYING. If not, write to
the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. */
/* Written by Michael I. Bushnell. */
#include "ufs.h"
#include <string.h>
#ifdef DONT_CACHE_MEMORY_OBJECTS
#define MAY_CACHE 0
#else
#define MAY_CACHE 1
#endif
static int indir_release (struct node *np, daddr_t bno, int level);
static void poke_pages (memory_object_t, vm_offset_t, vm_offset_t);
/* Implement the diskfs_truncate callback; sse <hurd/diskfs.h> for the
interface description. */
error_t
diskfs_truncate (struct node *np,
off_t length)
{
int offset;
struct dinode *di = dino (np->dn->number);
volatile int blocksfreed = 0;
error_t err;
int i;
struct iblock_spec indirs[NIADDR + 1];
volatile daddr_t lbn;
struct user_pager_info *upi;
if (length >= np->dn_stat.st_size)
return 0;
assert (!diskfs_readonly);
/* First check to see if this is a kludged symlink; if so
this is special. */
if (direct_symlink_extension && S_ISLNK (np->dn_stat.st_mode)
&& np->dn_stat.st_size < sblock->fs_maxsymlinklen)
{
error_t err;
err = diskfs_catch_exception ();
if (err)
return err;
bzero (di->di_shortlink + length, np->dn_stat.st_size - length);
diskfs_end_catch_exception ();
np->dn_stat.st_size = length;
np->dn_set_ctime = np->dn_set_mtime = 1;
return 0;
}
/* If the file is not being trucated to a block boundary,
the zero the partial bit in the new last block. */
offset = blkoff (sblock, length);
if (offset)
{
int bsize; /* size of new last block */
int savesize = np->allocsize;
np->allocsize = length; /* temporary */
bsize = blksize (sblock, np, lblkno (sblock, length));
np->allocsize = savesize;
diskfs_node_rdwr (np, (void *) zeroblock, length,
bsize - offset, 1, 0, 0);
diskfs_file_update (np, 1);
}
/* Now flush all the data past the new size from the kernel.
Also force any delayed copies of this data to take place
immediately. (We are implicitly changing the data to zeros
and doing it without the kernel's immediate knowledge;
accordingl we must help out the kernel thusly.) */
spin_lock (&node2pagelock);
upi = np->dn->fileinfo;
if (upi)
ports_port_ref (upi->p);
spin_unlock (&node2pagelock);
if (upi)
{
mach_port_t obj;
pager_change_attributes (upi->p, MAY_CACHE,
MEMORY_OBJECT_COPY_NONE, 1);
obj = diskfs_get_filemap (np, VM_PROT_READ | VM_PROT_WRITE);
poke_pages (obj, round_page (length), round_page (np->allocsize));
mach_port_deallocate (mach_task_self (), obj);
pager_flush_some (upi->p, round_page (length),
np->allocsize - length, 1);
ports_port_deref (upi->p);
}
rwlock_writer_lock (&np->dn->allocptrlock);
/* Update the size on disk; fsck will finish freeing blocks if necessary
should we crash. */
np->dn_stat.st_size = length;
np->dn_set_mtime = 1;
np->dn_set_ctime = 1;
diskfs_node_update (np, 1);
/* Find out the location information for the last block to
be retained */
lbn = lblkno (sblock, length - 1);
err = fetch_indir_spec (np, lbn, indirs);
/* err XXX */
/* We don't support triple indirs */
assert (indirs[3].offset == -2);
err = diskfs_catch_exception ();
/* err XXX */
/* BSD carefully finds out how far to clear; it's vastly simpler
to just clear everything after the new last block. */
/* Free direct blocks */
if (indirs[0].offset < 0)
{
/* ...mapped from the inode. */
for (i = lbn + 1; i < NDADDR; i++)
if (di->di_db[i])
{
long bsize = blksize (sblock, np, i);
ffs_blkfree (np, di->di_db[i], bsize);
di->di_db[i] = 0;
blocksfreed += btodb (bsize);
}
}
else
{
/* ... or mapped from sindir */
if (indirs[1].bno)
{
daddr_t *sindir = indir_block (indirs[1].bno);
for (i = indirs[0].offset + 1; i < NINDIR (sblock); i++)
if (sindir[i])
{
ffs_blkfree (np, sindir[i], sblock->fs_bsize);
sindir[i] = 0;
blocksfreed += btodb (sblock->fs_bsize);
}
record_poke (sindir, sblock->fs_bsize);
}
}
/* Free single indirect blocks */
if (indirs[1].offset < 0)
{
/* ...mapped from the inode */
if (di->di_ib[INDIR_SINGLE] && indirs[1].offset == -2)
{
blocksfreed += indir_release (np, di->di_ib[INDIR_SINGLE],
INDIR_SINGLE);
di->di_ib[INDIR_SINGLE] = 0;
}
}
else
{
/* ...or mapped from dindir */
if (indirs[2].bno)
{
daddr_t *dindir = indir_block (indirs[2].bno);
for (i = indirs[1].offset + 1; i < NINDIR (sblock); i++)
if (dindir[i])
{
blocksfreed += indir_release (np, dindir[i], INDIR_SINGLE);
dindir[i] = 0;
}
record_poke (dindir, sblock->fs_bsize);
}
}
/* Free double indirect block */
assert (indirs[2].offset < 0); /* which must be mapped from the inode */
if (indirs[2].offset == -2)
{
if (di->di_ib[INDIR_DOUBLE])
{
blocksfreed += indir_release (np, di->di_ib[INDIR_DOUBLE],
INDIR_DOUBLE);
di->di_ib[INDIR_DOUBLE] = 0;
}
}
/* Finally, check to see if the new last direct block is
changing size; if so release any frags necessary. */
if (lbn >= 0 && lbn < NDADDR && di->di_db[lbn])
{
long oldspace, newspace;
daddr_t bn;
bn = di->di_db[lbn];
oldspace = blksize (sblock, np, lbn);
np->allocsize = fragroundup (sblock, length);
newspace = blksize (sblock, np, lbn);
assert (newspace);
if (oldspace - newspace)
{
bn += numfrags (sblock, newspace);
ffs_blkfree (np, bn, oldspace - newspace);
blocksfreed += btodb (oldspace - newspace);
}
}
else
{
if (lbn > NDADDR)
np->allocsize = blkroundup (sblock, length);
else
np->allocsize = fragroundup (sblock, length);
}
record_poke (di, sizeof (struct dinode));
np->dn_stat.st_blocks -= blocksfreed;
np->dn_set_ctime = 1;
diskfs_node_update (np, 1);
rwlock_writer_unlock (&np->dn->allocptrlock);
/* At this point the last block (as defined by np->allocsize)
might not be allocated. We need to allocate it to maintain
the rule that the last block of a file is always allocated. */
if (np->allocsize && indirs[0].bno == 0)
{
/* The strategy is to reduce LBN until we get one that's allocated;
then reduce allocsize accordingly, then call diskfs_grow. */
do
err = fetch_indir_spec (np, --lbn, indirs);
/* err XXX */
while (indirs[0].bno == 0 && lbn >= 0);
assert ((lbn + 1) * sblock->fs_bsize < np->allocsize);
np->allocsize = (lbn + 1) * sblock->fs_bsize;
diskfs_grow (np, length, 0);
}
diskfs_end_catch_exception ();
/* Now we can permit delayed copies again. */
spin_lock (&node2pagelock);
upi = np->dn->fileinfo;
if (upi)
ports_port_ref (upi->p);
spin_unlock (&node2pagelock);
if (upi)
{
pager_change_attributes (upi->p, MAY_CACHE,
MEMORY_OBJECT_COPY_DELAY, 0);
ports_port_deref (upi->p);
}
return err;
}
/* Free indirect block BNO of level LEVEL; recursing if necessary
to free other indirect blocks. Return the number of disk
blocks freed. */
static int
indir_release (struct node *np, daddr_t bno, int level)
{
int count = 0;
daddr_t *addrs;
int i;
struct dirty_indir *d, *prev, *next;
assert (bno);
addrs = indir_block (bno);
for (i = 0; i < NINDIR (sblock); i++)
if (addrs[i])
{
if (level == INDIR_SINGLE)
{
ffs_blkfree (np, addrs[i], sblock->fs_bsize);
count += btodb (sblock->fs_bsize);
}
else
count += indir_release (np, addrs[i], level - 1);
}
/* Subtlety: this block is no longer necessary; the information
the kernel has cached corresponding to ADDRS is now unimportant.
Consider that if this block is allocated to a file, it will then
be double cached and the kernel might decide to write out
the disk_image version of the block. So we have to flush
the block from the kernel's memory, making sure we do it
synchronously--and BEFORE we attach it to the free list
with ffs_blkfree. */
pager_flush_some (diskpager->p, fsaddr (sblock, bno), sblock->fs_bsize, 1);
/* We should also take this block off the inode's list of
dirty indirect blocks if it's there. */
prev = 0;
d = np->dn->dirty;
while (d)
{
next = d->next;
if (d->bno == bno)
{
if (prev)
prev->next = next;
else
np->dn->dirty = next;
free (d);
}
else
{
prev = d;
next = d->next;
}
d = next;
}
/* Free designated block */
ffs_blkfree (np, bno, sblock->fs_bsize);
count += btodb (sblock->fs_bsize);
return count;
}
/* Implement the diskfs_grow callback; see <hurd/diskfs.h> for the
interface description. */
error_t
diskfs_grow (struct node *np,
off_t end,
struct protid *cred)
{
daddr_t lbn, olbn;
int size, osize;
error_t err;
struct dinode *di = dino (np->dn->number);
off_t poke_off = 0;
size_t poke_len = 0;
/* Zero an sblock->fs_bsize piece of disk starting at BNO,
synchronously. We do this on newly allocated indirect
blocks before setting the pointer to them to ensure that an
indirect block absolutely never points to garbage. */
void zero_disk_block (int bno)
{
bzero (indir_block (bno), sblock->fs_bsize);
sync_disk_blocks (bno, sblock->fs_bsize, 1);
};
/* Check to see if we don't actually have to do anything */
if (end <= np->allocsize)
return 0;
assert (!diskfs_readonly);
/* The new last block of the file. */
lbn = lblkno (sblock, end - 1);
/* This is the size of that block if it is in the NDADDR array. */
size = fragroundup (sblock, blkoff (sblock, end));
if (size == 0)
size = sblock->fs_bsize;
rwlock_writer_lock (&np->dn->allocptrlock);
/* The old last block of the file. */
olbn = lblkno (sblock, np->allocsize - 1);
/* This is the size of that block if it is in the NDADDR array. */
osize = fragroundup (sblock, blkoff (sblock, np->allocsize));
if (osize == 0)
osize = sblock->fs_bsize;
/* If this end point is a new block and the file currently
has a fragment, then expand the fragment to a full block. */
if (np->allocsize && olbn < NDADDR && olbn < lbn)
{
if (osize < sblock->fs_bsize)
{
daddr_t old_pbn, bno;
err = ffs_realloccg (np, olbn,
ffs_blkpref (np, lbn, lbn, di->di_db),
osize, sblock->fs_bsize, &bno, cred);
if (err)
goto out;
old_pbn = di->di_db[olbn];
di->di_db[olbn] = bno;
record_poke (di, sizeof (struct dinode));
np->dn_set_ctime = 1;
diskfs_device_write_sync (fsbtodb (sblock, bno) + btodb (osize),
zeroblock, sblock->fs_bsize - osize);
if (bno != old_pbn)
{
/* Make sure the old contents get written out
to the new address by poking the pages. */
poke_off = olbn * sblock->fs_bsize;
poke_len = osize;
}
}
}
if (lbn < NDADDR)
{
daddr_t bno, old_pbn = di->di_db[lbn];
if (old_pbn != 0)
{
/* The last block is already allocated. Therefore we
must be expanding the fragment. Make sure that's really
what we're up to. */
assert (size > osize);
assert (lbn == olbn);
err = ffs_realloccg (np, lbn,
ffs_blkpref (np, lbn, lbn, di->di_db),
osize, size, &bno, cred);
if (err)
goto out;
di->di_db[lbn] = bno;
record_poke (di, sizeof (struct dinode));
np->dn_set_ctime = 1;
diskfs_device_write_sync (fsbtodb (sblock, bno) + btodb (osize),
zeroblock, size - osize);
if (bno != old_pbn)
{
assert (!poke_len);
/* Make sure the old contents get written out to
the new address by poking the pages. */
poke_off = lbn * sblock->fs_bsize;
poke_len = osize;
}
}
else
{
/* Allocate a new last block. */
err = ffs_alloc (np, lbn,
ffs_blkpref (np, lbn, lbn, di->di_db),
size, &bno, cred);
if (err)
goto out;
di->di_db[lbn] = bno;
record_poke (di, sizeof (struct dinode));
np->dn_set_ctime = 1;
diskfs_device_write_sync (fsbtodb (sblock, bno), zeroblock, size);
}
}
else
{
struct iblock_spec indirs[NIADDR + 1];
daddr_t *siblock;
daddr_t bno;
/* Count the number of levels of indirection. */
err = fetch_indir_spec (np, lbn, indirs);
if (err)
goto out;
/* Make sure we didn't miss the NDADDR case
above somehow. */
assert (indirs[0].offset != -1);
/* See if we need a triple indirect block; fail if so. */
assert (indirs[1].offset == -1 || indirs[2].offset == -1);
/* Check to see if this block is allocated. If it is
that's an error. */
assert (indirs[0].bno == 0);
/* We need to set SIBLOCK to the single indirect block
array; see if the single indirect block is allocated. */
if (indirs[1].bno == 0)
{
/* Allocate it. */
if (indirs[1].offset == -1)
{
err = ffs_alloc (np, lbn,
ffs_blkpref (np, lbn, INDIR_SINGLE, di->di_ib),
sblock->fs_bsize, &bno, 0);
if (err)
goto out;
zero_disk_block (bno);
indirs[1].bno = di->di_ib[INDIR_SINGLE] = bno;
record_poke (di, sizeof (struct dinode));
}
else
{
daddr_t *diblock;
/* We need to set diblock to the double indirect block
array; see if the double indirect block is allocated. */
if (indirs[2].bno == 0)
{
/* This assert because triple indirection is not
supported. */
assert (indirs[2].offset == -1);
err = ffs_alloc (np, lbn,
ffs_blkpref (np, lbn,
INDIR_DOUBLE, di->di_ib),
sblock->fs_bsize, &bno, 0);
if (err)
goto out;
zero_disk_block (bno);
indirs[2].bno = di->di_ib[INDIR_DOUBLE] = bno;
record_poke (di, sizeof (struct dinode));
}
diblock = indir_block (indirs[2].bno);
mark_indir_dirty (np, indirs[2].bno);
/* Now we can allocate the single indirect block */
err = ffs_alloc (np, lbn,
ffs_blkpref (np, lbn,
indirs[1].offset, diblock),
sblock->fs_bsize, &bno, 0);
if (err)
goto out;
zero_disk_block (bno);
indirs[1].bno = diblock[indirs[1].offset] = bno;
record_poke (diblock, sblock->fs_bsize);
}
}
siblock = indir_block (indirs[1].bno);
mark_indir_dirty (np, indirs[1].bno);
/* Now we can allocate the data block. */
err = ffs_alloc (np, lbn,
ffs_blkpref (np, lbn, indirs[0].offset, siblock),
sblock->fs_bsize, &bno, 0);
if (err)
goto out;
indirs[0].bno = siblock[indirs[0].offset] = bno;
record_poke (siblock, sblock->fs_bsize);
diskfs_device_write_sync (fsbtodb (sblock, bno),
zeroblock, sblock->fs_bsize);
}
out:
if (!err)
{
int newallocsize;
if (lbn < NDADDR)
newallocsize = lbn * sblock->fs_bsize + size;
else
newallocsize = (lbn + 1) * sblock->fs_bsize;
assert (newallocsize > np->allocsize);
np->allocsize = newallocsize;
}
rwlock_writer_unlock (&np->dn->allocptrlock);
/* If we expanded a fragment, then POKE_LEN will be set.
We need to poke the requested amount of the memory object
so that the kernel will write out the data to the new location
at a suitable time. */
if (poke_len)
{
mach_port_t obj;
obj = diskfs_get_filemap (np, VM_PROT_READ | VM_PROT_WRITE);
poke_pages (obj, trunc_page (poke_off),
round_page (poke_off + poke_len));
mach_port_deallocate (mach_task_self (), obj);
}
return err;
}
/* Write something to each page from START to END inclusive of memory
object OBJ, but make sure the data doesns't actually change. */
static void
poke_pages (memory_object_t obj,
vm_offset_t start,
vm_offset_t end)
{
vm_address_t addr, poke;
vm_size_t len;
error_t err;
while (start < end)
{
len = 8 * vm_page_size;
if (len > end - start)
len = end - start;
addr = 0;
err = vm_map (mach_task_self (), &addr, len, 0, 1, obj, start, 0,
VM_PROT_WRITE|VM_PROT_READ, VM_PROT_READ|VM_PROT_WRITE, 0);
if (!err)
{
for (poke = addr; poke < addr + len; poke += vm_page_size)
*(volatile int *)poke = *(volatile int *)poke;
vm_deallocate (mach_task_self (), addr, len);
}
start += len;
}
}
|