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|
/* Disk allocation routines
Copyright (C) 1993,94,95,96,98,2002 Free Software Foundation, Inc.
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. */
/* Modified from UCB by Michael I. Bushnell. */
/*
* Copyright (c) 1982, 1986, 1989, 1993
* The Regents of the University of California. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the University of
* California, Berkeley and its contributors.
* 4. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* @(#)ffs_alloc.c 8.8 (Berkeley) 2/21/94
*/
#include "ufs.h"
#include <stdio.h>
#include <string.h>
/* These don't work *at all* here; don't even try setting them. */
#undef DIAGNOSTIC
#undef QUOTA
extern u_long nextgennumber;
spin_lock_t alloclock = SPIN_LOCK_INITIALIZER;
/* Forward declarations */
static u_long ffs_hashalloc (struct node *, int, long, int,
u_long (*)(struct node *, int, daddr_t, int));
static u_long ffs_alloccg (struct node *, int, daddr_t, int);
static daddr_t ffs_fragextend (struct node *, int, long, int, int);
static ino_t ffs_dirpref (struct fs *);
static u_long ffs_nodealloccg (struct node *, int, daddr_t, int);
static daddr_t ffs_alloccgblk (struct fs *, struct cg *, daddr_t);
static daddr_t ffs_mapsearch (struct fs *, struct cg *, daddr_t, int);
static void ffs_clusteracct (struct fs *, struct cg *, daddr_t, int);
/* Sync all allocation information and nod eNP if diskfs_synchronous. */
inline void
alloc_sync (struct node *np)
{
if (diskfs_synchronous)
{
if (np)
diskfs_node_update (np, 1);
copy_sblock ();
diskfs_set_hypermetadata (1, 0);
sync_disk (1);
}
}
/* Byteswap everything in CGP. */
void
swab_cg (struct cg *cg)
{
int i, j;
if (swab_long (cg->cg_magic) == CG_MAGIC
|| cg->cg_magic == CG_MAGIC)
{
cg->cg_magic = swab_long (cg->cg_magic);
cg->cg_time = swab_long (cg->cg_time);
cg->cg_cgx = swab_long (cg->cg_cgx);
cg->cg_ncyl = swab_short (cg->cg_ncyl);
cg->cg_niblk = swab_short (cg->cg_niblk);
cg->cg_cs.cs_ndir = swab_long (cg->cg_cs.cs_ndir);
cg->cg_cs.cs_nbfree = swab_long (cg->cg_cs.cs_nbfree);
cg->cg_cs.cs_nifree = swab_long (cg->cg_cs.cs_nifree);
cg->cg_cs.cs_nffree = swab_long (cg->cg_cs.cs_nffree);
cg->cg_rotor = swab_long (cg->cg_rotor);
cg->cg_irotor = swab_long (cg->cg_irotor);
for (i = 0; i < MAXFRAG; i++)
cg->cg_frsum[i] = swab_long (cg->cg_frsum[i]);
cg->cg_btotoff = swab_long (cg->cg_btotoff);
cg->cg_boff = swab_long (cg->cg_boff);
cg->cg_iusedoff = swab_long (cg->cg_iusedoff);
cg->cg_freeoff = swab_long (cg->cg_freeoff);
cg->cg_nextfreeoff = swab_long (cg->cg_nextfreeoff);
cg->cg_clustersumoff = swab_long (cg->cg_clustersumoff);
cg->cg_clusteroff = swab_long (cg->cg_clusteroff);
cg->cg_nclusterblks = swab_long (cg->cg_nclusterblks);
/* blktot map */
for (i = 0; i < cg->cg_ncyl; i++)
cg_blktot(cg)[i] = swab_long (cg_blktot(cg)[i]);
/* blks map */
for (i = 0; i < cg->cg_ncyl; i++)
for (j = 0; j < sblock->fs_nrpos; j++)
cg_blks(sblock, cg, i)[j] = swab_short (cg_blks (sblock, cg, i)[j]);
for (i = 0; i < sblock->fs_contigsumsize; i++)
cg_clustersum(cg)[i] = swab_long (cg_clustersum(cg)[i]);
/* inosused, blksfree, and cg_clustersfree are char arrays */
}
else
{
/* Old format cylinder group... */
struct ocg *ocg = (struct ocg *) cg;
if (swab_long (ocg->cg_magic) != CG_MAGIC
&& ocg->cg_magic != CG_MAGIC)
return;
ocg->cg_time = swab_long (ocg->cg_time);
ocg->cg_cgx = swab_long (ocg->cg_cgx);
ocg->cg_ncyl = swab_short (ocg->cg_ncyl);
ocg->cg_niblk = swab_short (ocg->cg_niblk);
ocg->cg_ndblk = swab_long (ocg->cg_ndblk);
ocg->cg_cs.cs_ndir = swab_long (ocg->cg_cs.cs_ndir);
ocg->cg_cs.cs_nbfree = swab_long (ocg->cg_cs.cs_nbfree);
ocg->cg_cs.cs_nifree = swab_long (ocg->cg_cs.cs_nifree);
ocg->cg_cs.cs_nffree = swab_long (ocg->cg_cs.cs_nffree);
ocg->cg_rotor = swab_long (ocg->cg_rotor);
ocg->cg_frotor = swab_long (ocg->cg_frotor);
ocg->cg_irotor = swab_long (ocg->cg_irotor);
for (i = 0; i < 8; i++)
ocg->cg_frsum[i] = swab_long (ocg->cg_frsum[i]);
for (i = 0; i < 32; i++)
ocg->cg_btot[i] = swab_long (ocg->cg_btot[i]);
for (i = 0; i < 32; i++)
for (j = 0; j < 8; j++)
ocg->cg_b[i][j] = swab_short (ocg->cg_b[i][j]);
ocg->cg_magic = swab_long (ocg->cg_magic);
}
}
/* Read cylinder group indexed CG. Set *CGPP to point at it.
Return 1 if caller should call release_cgp when we're done with it;
otherwise zero. */
int
read_cg (int cg, struct cg **cgpp)
{
struct cg *diskcg = cg_locate (cg);
if (swab_disk)
{
*cgpp = malloc (sblock->fs_cgsize);
bcopy (diskcg, *cgpp, sblock->fs_cgsize);
swab_cg (*cgpp);
return 1;
}
else
{
*cgpp = diskcg;
return 0;
}
}
/* Caller of read_cg is done with cg; write it back to disk (swapping it
along the way) and free the memory allocated in read_cg. */
void
release_cg (struct cg *cgp)
{
int cgx = cgp->cg_cgx;
swab_cg (cgp);
bcopy (cgp, cg_locate (cgx), sblock->fs_cgsize);
free (cgp);
}
/*
* Allocate a block in the file system.
*
* The size of the requested block is given, which must be some
* multiple of fs_fsize and <= fs_bsize.
* A preference may be optionally specified. If a preference is given
* the following hierarchy is used to allocate a block:
* 1) allocate the requested block.
* 2) allocate a rotationally optimal block in the same cylinder.
* 3) allocate a block in the same cylinder group.
* 4) quadradically rehash into other cylinder groups, until an
* available block is located.
* If no block preference is given the following heirarchy is used
* to allocate a block:
* 1) allocate a block in the cylinder group that contains the
* inode for the file.
* 2) quadradically rehash into other cylinder groups, until an
* available block is located.
*/
error_t
ffs_alloc(register struct node *np,
daddr_t lbn,
daddr_t bpref,
int size,
daddr_t *bnp,
struct protid *cred)
{
register struct fs *fs;
daddr_t bno;
int cg;
*bnp = 0;
fs = sblock;
#ifdef DIAGNOSTIC
if ((u_int)size > fs->fs_bsize || fragoff(fs, size) != 0) {
printf("dev = 0x%x, bsize = %d, size = %d, fs = %s\n",
ip->i_dev, fs->fs_bsize, size, fs->fs_fsmnt);
panic("ffs_alloc: bad size");
}
assert (cred);
#endif /* DIAGNOSTIC */
spin_lock (&alloclock);
if (size == fs->fs_bsize && fs->fs_cstotal.cs_nbfree == 0)
goto nospace;
if (cred && !idvec_contains (cred->user->uids, 0)
&& freespace(fs, fs->fs_minfree) <= 0)
goto nospace;
#ifdef QUOTA
if (error = chkdq(ip, (long)btodb(size), cred, 0))
return (error);
#endif
if (bpref >= fs->fs_size)
bpref = 0;
if (bpref == 0)
cg = ino_to_cg(fs, np->dn->number);
else
cg = dtog(fs, bpref);
bno = (daddr_t)ffs_hashalloc(np, cg, (long)bpref, size,
(u_long (*)())ffs_alloccg);
if (bno > 0) {
spin_unlock (&alloclock);
np->dn_stat.st_blocks += btodb(size);
np->dn_set_ctime = 1;
np->dn_set_mtime = 1;
*bnp = bno;
alloc_sync (np);
return (0);
}
#ifdef QUOTA
/*
* Restore user's disk quota because allocation failed.
*/
(void) chkdq(ip, (long)-btodb(size), cred, FORCE);
#endif
nospace:
spin_unlock (&alloclock);
printf ("file system full");
/* ffs_fserr(fs, cred->cr_uid, "file system full"); */
/* uprintf("\n%s: write failed, file system is full\n", fs->fs_fsmnt); */
return (ENOSPC);
}
/*
* Reallocate a fragment to a bigger size
*
* The number and size of the old block is given, and a preference
* and new size is also specified. The allocator attempts to extend
* the original block. Failing that, the regular block allocator is
* invoked to get an appropriate block.
*/
error_t
ffs_realloccg(register struct node *np,
daddr_t lbprev,
volatile daddr_t bpref,
int osize,
int nsize,
daddr_t *pbn,
struct protid *cred)
{
register struct fs *fs;
int cg, error;
volatile int request;
daddr_t bprev, bno;
*pbn = 0;
fs = sblock;
#ifdef DIAGNOSTIC
if ((u_int)osize > fs->fs_bsize || fragoff(fs, osize) != 0 ||
(u_int)nsize > fs->fs_bsize || fragoff(fs, nsize) != 0) {
printf(
"dev = 0x%x, bsize = %d, osize = %d, nsize = %d, fs = %s\n",
ip->i_dev, fs->fs_bsize, osize, nsize, fs->fs_fsmnt);
panic("ffs_realloccg: bad size");
}
if (cred == NOCRED)
panic("ffs_realloccg: missing credential\n");
#endif /* DIAGNOSTIC */
spin_lock (&alloclock);
if (!idvec_contains (cred->user->uids, 0)
&& freespace(fs, fs->fs_minfree) <= 0)
goto nospace;
error = diskfs_catch_exception ();
if (error)
return error;
bprev = read_disk_entry ((dino (np->dn->number))->di_db[lbprev]);
diskfs_end_catch_exception ();
assert ("old block not allocated" && bprev);
#if 0 /* Not needed in GNU Hurd ufs */
/*
* Allocate the extra space in the buffer.
*/
if (error = bread(ITOV(ip), lbprev, osize, NOCRED, &bp)) {
brelse(bp);
return (error);
}
#ifdef QUOTA
if (error = chkdq(ip, (long)btodb(nsize - osize), cred, 0)) {
brelse(bp);
return (error);
}
#endif
#endif /* 0 */
/*
* Check for extension in the existing location.
*/
cg = dtog(fs, bprev);
bno = ffs_fragextend(np, cg, (long)bprev, osize, nsize);
if (bno) {
assert (bno == bprev);
spin_unlock (&alloclock);
np->dn_stat.st_blocks += btodb(nsize - osize);
np->dn_set_ctime = 1;
np->dn_set_mtime = 1;
*pbn = bno;
#if 0 /* Not done this way in GNU Hurd ufs. */
allocbuf(bp, nsize);
bp->b_flags |= B_DONE;
bzero((char *)bp->b_data + osize, (u_int)nsize - osize);
*bpp = bp;
#endif
alloc_sync (np);
return (0);
}
/*
* Allocate a new disk location.
*/
if (bpref >= fs->fs_size)
bpref = 0;
switch ((int)fs->fs_optim) {
case FS_OPTSPACE:
/*
* Allocate an exact sized fragment. Although this makes
* best use of space, we will waste time relocating it if
* the file continues to grow. If the fragmentation is
* less than half of the minimum free reserve, we choose
* to begin optimizing for time.
*/
request = nsize;
if (fs->fs_minfree < 5 ||
fs->fs_cstotal.cs_nffree >
fs->fs_dsize * fs->fs_minfree / (2 * 100))
break;
printf ("%s: optimization changed from SPACE to TIME\n",
fs->fs_fsmnt);
fs->fs_optim = FS_OPTTIME;
break;
case FS_OPTTIME:
/*
* At this point we have discovered a file that is trying to
* grow a small fragment to a larger fragment. To save time,
* we allocate a full sized block, then free the unused portion.
* If the file continues to grow, the `ffs_fragextend' call
* above will be able to grow it in place without further
* copying. If aberrant programs cause disk fragmentation to
* grow within 2% of the free reserve, we choose to begin
* optimizing for space.
*/
request = fs->fs_bsize;
if (fs->fs_cstotal.cs_nffree <
fs->fs_dsize * (fs->fs_minfree - 2) / 100)
break;
printf ("%s: optimization changed from TIME to SPACE\n",
fs->fs_fsmnt);
fs->fs_optim = FS_OPTSPACE;
break;
default:
assert (0);
/* NOTREACHED */
}
bno = (daddr_t)ffs_hashalloc(np, cg, (long)bpref, request,
(u_long (*)())ffs_alloccg);
if (bno > 0) {
#if 0 /* Not necessary in GNU Hurd ufs */
bp->b_blkno = fsbtodb(fs, bno);
(void) vnode_pager_uncache(ITOV(ip));
#endif
/* Commented out here for Hurd; we don't want to free this until we've
saved the old contents. Callers are responsible for freeing the
block when they are done with it. */
/* ffs_blkfree(np, bprev, (long)osize); */
if (nsize < request)
ffs_blkfree(np, bno + numfrags(fs, nsize),
(long)(request - nsize));
spin_unlock (&alloclock);
np->dn_stat.st_blocks += btodb(nsize - osize);
np->dn_set_mtime = 1;
np->dn_set_ctime = 1;
*pbn = bno;
#if 0 /* Not done this way in GNU Hurd ufs */
allocbuf(bp, nsize);
bp->b_flags |= B_DONE;
bzero((char *)bp->b_data + osize, (u_int)nsize - osize);
*bpp = bp;
#endif /* 0 */
alloc_sync (np);
return (0);
}
#ifdef QUOTA
/*
* Restore user's disk quota because allocation failed.
*/
(void) chkdq(ip, (long)-btodb(nsize - osize), cred, FORCE);
#endif
#if 0 /* Not necesarry in GNU Hurd ufs */
brelse(bp);
#endif
nospace:
/*
* no space available
*/
spin_unlock (&alloclock);
printf ("file system full");
/* ffs_fserr(fs, cred->cr_uid, "file system full"); */
/* uprintf("\n%s: write failed, file system is full\n", fs->fs_fsmnt); */
return (ENOSPC);
}
#if 0 /* Not used (yet?) in GNU Hurd ufs */
/*
* Reallocate a sequence of blocks into a contiguous sequence of blocks.
*
* The vnode and an array of buffer pointers for a range of sequential
* logical blocks to be made contiguous is given. The allocator attempts
* to find a range of sequential blocks starting as close as possible to
* an fs_rotdelay offset from the end of the allocation for the logical
* block immediately preceeding the current range. If successful, the
* physical block numbers in the buffer pointers and in the inode are
* changed to reflect the new allocation. If unsuccessful, the allocation
* is left unchanged. The success in doing the reallocation is returned.
* Note that the error return is not reflected back to the user. Rather
* the previous block allocation will be used.
*/
#include <sys/sysctl.h>
int doasyncfree = 1;
struct ctldebug debug14 = { "doasyncfree", &doasyncfree };
int
ffs_reallocblks(ap)
struct vop_reallocblks_args /* {
struct vnode *a_vp;
struct cluster_save *a_buflist;
} */ *ap;
{
struct fs *fs;
struct inode *ip;
struct vnode *vp;
struct buf *sbp, *ebp;
daddr_t *bap, *sbap, *ebap;
struct cluster_save *buflist;
daddr_t start_lbn, end_lbn, soff, eoff, newblk, blkno;
struct indir start_ap[NIADDR + 1], end_ap[NIADDR + 1], *idp;
int i, len, start_lvl, end_lvl, pref, ssize;
vp = ap->a_vp;
ip = VTOI(vp);
fs = ip->i_fs;
if (fs->fs_contigsumsize <= 0)
return (ENOSPC);
buflist = ap->a_buflist;
len = buflist->bs_nchildren;
start_lbn = buflist->bs_children[0]->b_lblkno;
end_lbn = start_lbn + len - 1;
#ifdef DIAGNOSTIC
for (i = 1; i < len; i++)
if (buflist->bs_children[i]->b_lblkno != start_lbn + i)
panic("ffs_reallocblks: non-cluster");
#endif
/*
* If the latest allocation is in a new cylinder group, assume that
* the filesystem has decided to move and do not force it back to
* the previous cylinder group.
*/
if (dtog(fs, dbtofsb(fs, buflist->bs_children[0]->b_blkno)) !=
dtog(fs, dbtofsb(fs, buflist->bs_children[len - 1]->b_blkno)))
return (ENOSPC);
if (ufs_getlbns(vp, start_lbn, start_ap, &start_lvl) ||
ufs_getlbns(vp, end_lbn, end_ap, &end_lvl))
return (ENOSPC);
/*
* Get the starting offset and block map for the first block.
*/
if (start_lvl == 0) {
sbap = &ip->i_db[0];
soff = start_lbn;
} else {
idp = &start_ap[start_lvl - 1];
if (bread(vp, idp->in_lbn, (int)fs->fs_bsize, NOCRED, &sbp)) {
brelse(sbp);
return (ENOSPC);
}
sbap = (daddr_t *)sbp->b_data;
soff = idp->in_off;
}
/*
* Find the preferred location for the cluster.
*/
pref = ffs_blkpref(ip, start_lbn, soff, sbap);
/*
* If the block range spans two block maps, get the second map.
*/
if (end_lvl == 0 || (idp = &end_ap[end_lvl - 1])->in_off + 1 >= len) {
ssize = len;
} else {
#ifdef DIAGNOSTIC
if (start_ap[start_lvl-1].in_lbn == idp->in_lbn)
panic("ffs_reallocblk: start == end");
#endif
ssize = len - (idp->in_off + 1);
if (bread(vp, idp->in_lbn, (int)fs->fs_bsize, NOCRED, &ebp))
goto fail;
ebap = (daddr_t *)ebp->b_data;
}
/*
* Search the block map looking for an allocation of the desired size.
*/
if ((newblk = (daddr_t)ffs_hashalloc(ip, dtog(fs, pref), (long)pref,
len, (u_long (*)())ffs_clusteralloc)) == 0)
goto fail;
/*
* We have found a new contiguous block.
*
* First we have to replace the old block pointers with the new
* block pointers in the inode and indirect blocks associated
* with the file.
*/
blkno = newblk;
for (bap = &sbap[soff], i = 0; i < len; i++, blkno += fs->fs_frag) {
if (i == ssize)
bap = ebap;
#ifdef DIAGNOSTIC
if (buflist->bs_children[i]->b_blkno != fsbtodb(fs, *bap))
panic("ffs_reallocblks: alloc mismatch");
#endif
*bap++ = blkno;
}
/*
* Next we must write out the modified inode and indirect blocks.
* For strict correctness, the writes should be synchronous since
* the old block values may have been written to disk. In practise
* they are almost never written, but if we are concerned about
* strict correctness, the `doasyncfree' flag should be set to zero.
*
* The test on `doasyncfree' should be changed to test a flag
* that shows whether the associated buffers and inodes have
* been written. The flag should be set when the cluster is
* started and cleared whenever the buffer or inode is flushed.
* We can then check below to see if it is set, and do the
* synchronous write only when it has been cleared.
*/
if (sbap != &ip->i_db[0]) {
if (doasyncfree)
bdwrite(sbp);
else
bwrite(sbp);
} else {
ip->i_flag |= IN_CHANGE | IN_UPDATE;
if (!doasyncfree)
VOP_UPDATE(vp, &time, &time, MNT_WAIT);
}
if (ssize < len)
if (doasyncfree)
bdwrite(ebp);
else
bwrite(ebp);
/*
* Last, free the old blocks and assign the new blocks to the buffers.
*/
for (blkno = newblk, i = 0; i < len; i++, blkno += fs->fs_frag) {
ffs_blkfree(ip, dbtofsb(fs, buflist->bs_children[i]->b_blkno),
fs->fs_bsize);
buflist->bs_children[i]->b_blkno = fsbtodb(fs, blkno);
}
return (0);
fail:
if (ssize < len)
brelse(ebp);
if (sbap != &ip->i_db[0])
brelse(sbp);
return (ENOSPC);
}
#endif /* 0 */
/*
* Allocate an inode in the file system.
*
* If allocating a directory, use ffs_dirpref to select the inode.
* If allocating in a directory, the following hierarchy is followed:
* 1) allocate the preferred inode.
* 2) allocate an inode in the same cylinder group.
* 3) quadradically rehash into other cylinder groups, until an
* available inode is located.
* If no inode preference is given the following heirarchy is used
* to allocate an inode:
* 1) allocate an inode in cylinder group 0.
* 2) quadradically rehash into other cylinder groups, until an
* available inode is located.
*/
/* This is now the diskfs_alloc_node callback from the diskfs library
(described in <hurd/diskfs.h>). It used to be ffs_valloc in BSD. */
error_t
diskfs_alloc_node (struct node *dir,
mode_t mode,
struct node **npp)
{
register struct fs *fs;
struct node *np;
ino_t ino, ipref;
int cg, error;
int sex;
fs = sblock;
spin_lock (&alloclock);
if (fs->fs_cstotal.cs_nifree == 0)
{
spin_unlock (&alloclock);
goto noinodes;
}
if (S_ISDIR (mode))
ipref = ffs_dirpref(fs);
else
ipref = dir->dn->number;
if (ipref >= fs->fs_ncg * fs->fs_ipg)
ipref = 0;
cg = ino_to_cg(fs, ipref);
ino = (ino_t)ffs_hashalloc(dir, cg, (long)ipref,
mode, ffs_nodealloccg);
spin_unlock (&alloclock);
if (ino == 0)
goto noinodes;
error = diskfs_cached_lookup (ino, &np);
assert ("duplicate allocation" && !np->dn_stat.st_mode);
assert (! (np->dn_stat.st_mode & S_IPTRANS));
if (np->dn_stat.st_blocks) {
printf("free inode %Ld had %Ld blocks\n",
ino, np->dn_stat.st_blocks);
np->dn_stat.st_blocks = 0;
np->dn_set_ctime = 1;
}
np->dn_stat.st_flags = 0;
/*
* Set up a new generation number for this inode.
*/
spin_lock (&gennumberlock);
sex = diskfs_mtime->seconds;
if (++nextgennumber < (u_long)sex)
nextgennumber = sex;
np->dn_stat.st_gen = nextgennumber;
spin_unlock (&gennumberlock);
*npp = np;
alloc_sync (np);
return (0);
noinodes:
printf ("out of inodes");
/* ffs_fserr(fs, ap->a_cred->cr_uid, "out of inodes"); */
/* uprintf("\n%s: create/symlink failed, no inodes free\n", fs->fs_fsmnt);*/
return (ENOSPC);
}
/*
* Find a cylinder to place a directory.
*
* The policy implemented by this algorithm is to select from
* among those cylinder groups with above the average number of
* free inodes, the one with the smallest number of directories.
*/
static ino_t
ffs_dirpref(register struct fs *fs)
{
int cg, minndir, mincg, avgifree;
avgifree = fs->fs_cstotal.cs_nifree / fs->fs_ncg;
minndir = fs->fs_ipg;
mincg = 0;
for (cg = 0; cg < fs->fs_ncg; cg++)
if (csum[cg].cs_ndir < minndir &&
csum[cg].cs_nifree >= avgifree) {
mincg = cg;
minndir = csum[cg].cs_ndir;
}
return ((ino_t)(fs->fs_ipg * mincg));
}
/*
* Select the desired position for the next block in a file. The file is
* logically divided into sections. The first section is composed of the
* direct blocks. Each additional section contains fs_maxbpg blocks.
*
* If no blocks have been allocated in the first section, the policy is to
* request a block in the same cylinder group as the inode that describes
* the file. If no blocks have been allocated in any other section, the
* policy is to place the section in a cylinder group with a greater than
* average number of free blocks. An appropriate cylinder group is found
* by using a rotor that sweeps the cylinder groups. When a new group of
* blocks is needed, the sweep begins in the cylinder group following the
* cylinder group from which the previous allocation was made. The sweep
* continues until a cylinder group with greater than the average number
* of free blocks is found. If the allocation is for the first block in an
* indirect block, the information on the previous allocation is unavailable;
* here a best guess is made based upon the logical block number being
* allocated.
*
* If a section is already partially allocated, the policy is to
* contiguously allocate fs_maxcontig blocks. The end of one of these
* contiguous blocks and the beginning of the next is physically separated
* so that the disk head will be in transit between them for at least
* fs_rotdelay milliseconds. This is to allow time for the processor to
* schedule another I/O transfer.
*/
daddr_t
ffs_blkpref(struct node *np,
daddr_t lbn,
int indx,
daddr_t *bap)
{
register struct fs *fs;
register int cg;
int avgbfree, startcg;
daddr_t nextblk;
fs = sblock;
spin_lock (&alloclock);
if (indx % fs->fs_maxbpg == 0 || bap[indx - 1] == 0) {
if (lbn < NDADDR) {
cg = ino_to_cg(fs, np->dn->number);
spin_unlock (&alloclock);
return (fs->fs_fpg * cg + fs->fs_frag);
}
/*
* Find a cylinder with greater than average number of
* unused data blocks.
*/
if (indx == 0 || bap[indx - 1] == 0)
startcg =
(ino_to_cg(fs, np->dn->number)
+ lbn / fs->fs_maxbpg);
else
startcg = dtog(fs,
read_disk_entry (bap[indx - 1])) + 1;
startcg %= fs->fs_ncg;
avgbfree = fs->fs_cstotal.cs_nbfree / fs->fs_ncg;
for (cg = startcg; cg < fs->fs_ncg; cg++)
if (csum[cg].cs_nbfree >= avgbfree) {
fs->fs_cgrotor = cg;
spin_unlock (&alloclock);
return (fs->fs_fpg * cg + fs->fs_frag);
}
for (cg = 0; cg <= startcg; cg++)
if (csum[cg].cs_nbfree >= avgbfree) {
fs->fs_cgrotor = cg;
spin_unlock (&alloclock);
return (fs->fs_fpg * cg + fs->fs_frag);
}
spin_unlock (&alloclock);
return 0;
}
spin_unlock (&alloclock);
/*
* One or more previous blocks have been laid out. If less
* than fs_maxcontig previous blocks are contiguous, the
* next block is requested contiguously, otherwise it is
* requested rotationally delayed by fs_rotdelay milliseconds.
*/
nextblk = read_disk_entry (bap[indx - 1]) + fs->fs_frag;
if (indx < fs->fs_maxcontig
|| (read_disk_entry (bap[indx - fs->fs_maxcontig]) +
blkstofrags(fs, fs->fs_maxcontig) != nextblk))
{
return (nextblk);
}
if (fs->fs_rotdelay != 0)
/*
* Here we convert ms of delay to frags as:
* (frags) = (ms) * (rev/sec) * (sect/rev) /
* ((sect/frag) * (ms/sec))
* then round up to the next block.
*/
nextblk += roundup(fs->fs_rotdelay * fs->fs_rps * fs->fs_nsect /
(NSPF(fs) * 1000), fs->fs_frag);
return (nextblk);
}
/*
* Implement the cylinder overflow algorithm.
*
* The policy implemented by this algorithm is:
* 1) allocate the block in its requested cylinder group.
* 2) quadradically rehash on the cylinder group number.
* 3) brute force search for a free block.
*/
/*VARARGS5*/
static u_long
ffs_hashalloc(struct node *np,
int cg,
long pref,
int size, /* size for data blocks, mode for inodes */
u_long (*allocator)())
{
register struct fs *fs;
long result;
int i, icg = cg;
fs = sblock;
/*
* 1: preferred cylinder group
*/
result = (*allocator)(np, cg, pref, size);
if (result)
return (result);
/*
* 2: quadratic rehash
*/
for (i = 1; i < fs->fs_ncg; i *= 2) {
cg += i;
if (cg >= fs->fs_ncg)
cg -= fs->fs_ncg;
result = (*allocator)(np, cg, 0, size);
if (result)
return (result);
}
/*
* 3: brute force search
* Note that we start at i == 2, since 0 was checked initially,
* and 1 is always checked in the quadratic rehash.
*/
cg = (icg + 2) % fs->fs_ncg;
for (i = 2; i < fs->fs_ncg; i++) {
result = (*allocator)(np, cg, 0, size);
if (result)
return (result);
cg++;
if (cg == fs->fs_ncg)
cg = 0;
}
return 0;
}
/*
* Determine whether a fragment can be extended.
*
* Check to see if the necessary fragments are available, and
* if they are, allocate them.
*/
static daddr_t
ffs_fragextend(struct node *np,
int cg,
long bprev,
int osize,
int nsize)
{
register struct fs *fs;
struct cg *cgp;
long bno;
int frags, bbase;
int i;
int releasecg;
fs = sblock;
if (csum[cg].cs_nffree < numfrags(fs, nsize - osize))
return 0;
frags = numfrags(fs, nsize);
bbase = fragnum(fs, bprev);
if (bbase > fragnum(fs, (bprev + frags - 1))) {
/* cannot extend across a block boundary */
return 0;
}
#if 0 /* Wrong for GNU Hurd ufs */
error = bread(ip->i_devvp, fsbtodb(fs, cgtod(fs, cg)),
(int)fs->fs_cgsize, NOCRED, &bp);
if (error) {
brelse(bp);
return (NULL);
}
cgp = (struct cg *)bp->b_data;
#else
releasecg = read_cg (cg, &cgp);
#endif
if (!cg_chkmagic(cgp)) {
/* brelse(bp); */
if (releasecg)
release_cg (cgp);
return 0;
}
cgp->cg_time = diskfs_mtime->seconds;
bno = dtogd(fs, bprev);
for (i = numfrags(fs, osize); i < frags; i++)
if (isclr(cg_blksfree(cgp), bno + i)) {
/* brelse(bp); */
if (releasecg)
release_cg (cgp);
return 0;
}
/*
* the current fragment can be extended
* deduct the count on fragment being extended into
* increase the count on the remaining fragment (if any)
* allocate the extended piece
*/
for (i = frags; i < fs->fs_frag - bbase; i++)
if (isclr(cg_blksfree(cgp), bno + i))
break;
cgp->cg_frsum[i - numfrags(fs, osize)]--;
if (i != frags)
cgp->cg_frsum[i - frags]++;
for (i = numfrags(fs, osize); i < frags; i++) {
clrbit(cg_blksfree(cgp), bno + i);
cgp->cg_cs.cs_nffree--;
fs->fs_cstotal.cs_nffree--;
csum[cg].cs_nffree--;
}
if (releasecg)
release_cg (cgp);
record_poke (cgp, sblock->fs_cgsize);
csum_dirty = 1;
sblock_dirty = 1;
fs->fs_fmod = 1;
/* bdwrite(bp); */
return (bprev);
}
/*
* Determine whether a block can be allocated.
*
* Check to see if a block of the appropriate size is available,
* and if it is, allocate it.
*/
static u_long
ffs_alloccg(struct node *np,
int cg,
daddr_t bpref,
int size)
{
register struct fs *fs;
struct cg *cgp;
register int i;
int bno, frags, allocsiz;
int releasecg;
fs = sblock;
if (csum[cg].cs_nbfree == 0 && size == fs->fs_bsize)
return 0;
#if 0 /* Not this way in GNU Hurd ufs */
error = bread(ip->i_devvp, fsbtodb(fs, cgtod(fs, cg)),
(int)fs->fs_cgsize, NOCRED, &bp);
if (error) {
brelse(bp);
return (NULL);
}
cgp = (struct cg *)bp->b_data;
#else
releasecg = read_cg (cg, &cgp);
#endif
if (!cg_chkmagic(cgp) ||
(cgp->cg_cs.cs_nbfree == 0 && size == fs->fs_bsize)) {
/* brelse(bp); */
if (releasecg)
release_cg (cgp);
return 0;
}
cgp->cg_time = diskfs_mtime->seconds;
if (size == fs->fs_bsize) {
bno = ffs_alloccgblk(fs, cgp, bpref);
/* bdwrite(bp); */
if (releasecg)
release_cg (cgp);
return (bno);
}
/*
* check to see if any fragments are already available
* allocsiz is the size which will be allocated, hacking
* it down to a smaller size if necessary
*/
frags = numfrags(fs, size);
for (allocsiz = frags; allocsiz < fs->fs_frag; allocsiz++)
if (cgp->cg_frsum[allocsiz] != 0)
break;
if (allocsiz == fs->fs_frag) {
/*
* no fragments were available, so a block will be
* allocated, and hacked up
*/
if (cgp->cg_cs.cs_nbfree == 0) {
/* brelse(bp); */
if (releasecg)
release_cg (cgp);
return 0;
}
bno = ffs_alloccgblk(fs, cgp, bpref);
bpref = dtogd(fs, bno);
for (i = frags; i < fs->fs_frag; i++)
setbit(cg_blksfree(cgp), bpref + i);
i = fs->fs_frag - frags;
cgp->cg_cs.cs_nffree += i;
fs->fs_cstotal.cs_nffree += i;
csum[cg].cs_nffree += i;
fs->fs_fmod = 1;
cgp->cg_frsum[i]++;
if (releasecg)
release_cg (cgp);
record_poke (cgp, sblock->fs_cgsize);
csum_dirty = 1;
sblock_dirty = 1;
/* bdwrite(bp); */
return (bno);
}
bno = ffs_mapsearch(fs, cgp, bpref, allocsiz);
if (bno < 0) {
/* brelse(bp); */
if (releasecg)
release_cg (cgp);
return 0;
}
for (i = 0; i < frags; i++)
clrbit(cg_blksfree(cgp), bno + i);
cgp->cg_cs.cs_nffree -= frags;
fs->fs_cstotal.cs_nffree -= frags;
csum[cg].cs_nffree -= frags;
fs->fs_fmod = 1;
cgp->cg_frsum[allocsiz]--;
if (frags != allocsiz)
cgp->cg_frsum[allocsiz - frags]++;
if (releasecg)
release_cg (cgp);
record_poke (cgp, sblock->fs_cgsize);
csum_dirty = 1;
sblock_dirty = 1;
/* bdwrite(bp); */
return (cg * fs->fs_fpg + bno);
}
/*
* Allocate a block in a cylinder group.
*
* This algorithm implements the following policy:
* 1) allocate the requested block.
* 2) allocate a rotationally optimal block in the same cylinder.
* 3) allocate the next available block on the block rotor for the
* specified cylinder group.
* Note that this routine only allocates fs_bsize blocks; these
* blocks may be fragmented by the routine that allocates them.
*/
static daddr_t
ffs_alloccgblk(register struct fs *fs,
register struct cg *cgp,
daddr_t bpref)
{
daddr_t bno, blkno;
int cylno, pos, delta;
short *cylbp;
register int i;
if (bpref == 0 || dtog(fs, bpref) != cgp->cg_cgx) {
bpref = cgp->cg_rotor;
goto norot;
}
bpref = blknum(fs, bpref);
bpref = dtogd(fs, bpref);
/*
* if the requested block is available, use it
*/
if (ffs_isblock(fs, cg_blksfree(cgp), fragstoblks(fs, bpref))) {
bno = bpref;
goto gotit;
}
/*
* check for a block available on the same cylinder
*/
cylno = cbtocylno(fs, bpref);
if (cg_blktot(cgp)[cylno] == 0)
goto norot;
if (fs->fs_cpc == 0) {
/*
* Block layout information is not available.
* Leaving bpref unchanged means we take the
* next available free block following the one
* we just allocated. Hopefully this will at
* least hit a track cache on drives of unknown
* geometry (e.g. SCSI).
*/
goto norot;
}
/*
* check the summary information to see if a block is
* available in the requested cylinder starting at the
* requested rotational position and proceeding around.
*/
cylbp = cg_blks(fs, cgp, cylno);
pos = cbtorpos(fs, bpref);
for (i = pos; i < fs->fs_nrpos; i++)
if (cylbp[i] > 0)
break;
if (i == fs->fs_nrpos)
for (i = 0; i < pos; i++)
if (cylbp[i] > 0)
break;
if (cylbp[i] > 0) {
/*
* found a rotational position, now find the actual
* block. A panic if none is actually there.
*/
pos = cylno % fs->fs_cpc;
bno = (cylno - pos) * fs->fs_spc / NSPB(fs);
assert (fs_postbl(fs, pos)[i] != -1);
for (i = fs_postbl(fs, pos)[i];; ) {
if (ffs_isblock(fs, cg_blksfree(cgp), bno + i)) {
bno = blkstofrags(fs, (bno + i));
goto gotit;
}
delta = fs_rotbl(fs)[i];
if (delta <= 0 ||
delta + i > fragstoblks(fs, fs->fs_fpg))
break;
i += delta;
}
printf("pos = %d, i = %d, fs = %s\n", pos, i, fs->fs_fsmnt);
assert (0);
}
norot:
/*
* no blocks in the requested cylinder, so take next
* available one in this cylinder group.
*/
bno = ffs_mapsearch(fs, cgp, bpref, (int)fs->fs_frag);
if (bno < 0)
return 0;
cgp->cg_rotor = bno;
gotit:
blkno = fragstoblks(fs, bno);
ffs_clrblock(fs, cg_blksfree(cgp), (long)blkno);
ffs_clusteracct(fs, cgp, blkno, -1);
cgp->cg_cs.cs_nbfree--;
fs->fs_cstotal.cs_nbfree--;
csum[cgp->cg_cgx].cs_nbfree--;
cylno = cbtocylno(fs, bno);
cg_blks(fs, cgp, cylno)[cbtorpos(fs, bno)]--;
cg_blktot(cgp)[cylno]--;
fs->fs_fmod = 1;
record_poke (cgp, sblock->fs_cgsize);
csum_dirty = 1;
sblock_dirty = 1;
return (cgp->cg_cgx * fs->fs_fpg + bno);
}
#if 0 /* Not needed in GNU Hurd ufs (yet?) */
/*
* Determine whether a cluster can be allocated.
*
* We do not currently check for optimal rotational layout if there
* are multiple choices in the same cylinder group. Instead we just
* take the first one that we find following bpref.
*/
static daddr_t
ffs_clusteralloc(ip, cg, bpref, len)
struct inode *ip;
int cg;
daddr_t bpref;
int len;
{
register struct fs *fs;
register struct cg *cgp;
struct buf *bp;
int i, run, bno, bit, map;
u_char *mapp;
fs = ip->i_fs;
if (fs->fs_cs(fs, cg).cs_nbfree < len)
return (NULL);
if (bread(ip->i_devvp, fsbtodb(fs, cgtod(fs, cg)), (int)fs->fs_cgsize,
NOCRED, &bp))
goto fail;
cgp = (struct cg *)bp->b_data;
if (!cg_chkmagic(cgp))
goto fail;
/*
* Check to see if a cluster of the needed size (or bigger) is
* available in this cylinder group.
*/
for (i = len; i <= fs->fs_contigsumsize; i++)
if (cg_clustersum(cgp)[i] > 0)
break;
if (i > fs->fs_contigsumsize)
goto fail;
/*
* Search the cluster map to find a big enough cluster.
* We take the first one that we find, even if it is larger
* than we need as we prefer to get one close to the previous
* block allocation. We do not search before the current
* preference point as we do not want to allocate a block
* that is allocated before the previous one (as we will
* then have to wait for another pass of the elevator
* algorithm before it will be read). We prefer to fail and
* be recalled to try an allocation in the next cylinder group.
*/
if (dtog(fs, bpref) != cg)
bpref = 0;
else
bpref = fragstoblks(fs, dtogd(fs, blknum(fs, bpref)));
mapp = &cg_clustersfree(cgp)[bpref / NBBY];
map = *mapp++;
bit = 1 << (bpref % NBBY);
for (run = 0, i = bpref; i < cgp->cg_nclusterblks; i++) {
if ((map & bit) == 0) {
run = 0;
} else {
run++;
if (run == len)
break;
}
if ((i & (NBBY - 1)) != (NBBY - 1)) {
bit <<= 1;
} else {
map = *mapp++;
bit = 1;
}
}
if (i == cgp->cg_nclusterblks)
goto fail;
/*
* Allocate the cluster that we have found.
*/
bno = cg * fs->fs_fpg + blkstofrags(fs, i - run + 1);
len = blkstofrags(fs, len);
for (i = 0; i < len; i += fs->fs_frag)
if (ffs_alloccgblk(fs, cgp, bno + i) != bno + i)
panic("ffs_clusteralloc: lost block");
brelse(bp);
return (bno);
fail:
brelse(bp);
return (0);
}
#endif
/*
* Determine whether an inode can be allocated.
*
* Check to see if an inode is available, and if it is,
* allocate it using the following policy:
* 1) allocate the requested inode.
* 2) allocate the next available inode after the requested
* inode in the specified cylinder group.
*/
static u_long
ffs_nodealloccg(struct node *np,
int cg,
daddr_t ipref,
int mode)
{
register struct fs *fs;
struct cg *cgp;
int start, len, loc, map, i;
int releasecg;
fs = sblock;
if (csum[cg].cs_nifree == 0)
return 0;
#if 0 /* Not this way in GNU Hurd ufs */
error = bread(ip->i_devvp, fsbtodb(fs, cgtod(fs, cg)),
(int)fs->fs_cgsize, NOCRED, &bp);
if (error) {
brelse(bp);
return (NULL);
}
cgp = (struct cg *)bp->b_data;
#else
releasecg = read_cg (cg, &cgp);
#endif
if (!cg_chkmagic(cgp) || cgp->cg_cs.cs_nifree == 0) {
/* brelse(bp); */
if (releasecg)
release_cg (cgp);
return 0;
}
cgp->cg_time = diskfs_mtime->seconds;
if (ipref) {
ipref %= fs->fs_ipg;
if (isclr(cg_inosused(cgp), ipref))
goto gotit;
}
start = cgp->cg_irotor / NBBY;
len = howmany(fs->fs_ipg - cgp->cg_irotor, NBBY);
loc = skpc(0xff, len, &cg_inosused(cgp)[start]);
if (loc == 0) {
len = start + 1;
start = 0;
loc = skpc(0xff, len, &cg_inosused(cgp)[0]);
assert (loc != 0);
}
i = start + len - loc;
map = cg_inosused(cgp)[i];
ipref = i * NBBY;
for (i = 1; i < (1 << NBBY); i <<= 1, ipref++) {
if ((map & i) == 0) {
cgp->cg_irotor = ipref;
goto gotit;
}
}
assert (0);
/* NOTREACHED */
gotit:
setbit(cg_inosused(cgp), ipref);
cgp->cg_cs.cs_nifree--;
fs->fs_cstotal.cs_nifree--;
csum[cg].cs_nifree--;
fs->fs_fmod = 1;
if ((mode & IFMT) == IFDIR) {
cgp->cg_cs.cs_ndir++;
fs->fs_cstotal.cs_ndir++;
csum[cg].cs_ndir++;
}
if (releasecg)
release_cg (cgp);
record_poke (cgp, sblock->fs_cgsize);
csum_dirty = 1;
sblock_dirty = 1;
/* bdwrite(bp); */
return (cg * fs->fs_ipg + ipref);
}
/*
* Free a block or fragment.
*
* The specified block or fragment is placed back in the
* free map. If a fragment is deallocated, a possible
* block reassembly is checked.
*/
void
ffs_blkfree(register struct node *np,
daddr_t bno,
long size)
{
register struct fs *fs;
struct cg *cgp;
daddr_t blkno;
int i, cg, blk, frags, bbase;
int releasecg;
fs = sblock;
assert ((u_int)size <= fs->fs_bsize && !fragoff (fs, size));
cg = dtog(fs, bno);
if ((u_int)bno >= fs->fs_size) {
printf("bad block %ld, ino %Ld\n", bno, np->dn->number);
/* ffs_fserr(fs, ip->i_uid, "bad block"); */
return;
}
#if 0 /* Not this way in GNU Hurd ufs */
error = bread(ip->i_devvp, fsbtodb(fs, cgtod(fs, cg)),
(int)fs->fs_cgsize, NOCRED, &bp);
if (error) {
brelse(bp);
return;
}
cgp = (struct cg *)bp->b_data;
#else
releasecg = read_cg (cg, &cgp);
#endif
if (!cg_chkmagic(cgp)) {
/* brelse(bp); */
if (releasecg)
release_cg (cgp);
return;
}
cgp->cg_time = diskfs_mtime->seconds;
bno = dtogd(fs, bno);
if (size == fs->fs_bsize) {
blkno = fragstoblks(fs, bno);
assert (!ffs_isblock(fs, cg_blksfree (cgp), blkno));
ffs_setblock(fs, cg_blksfree(cgp), blkno);
ffs_clusteracct(fs, cgp, blkno, 1);
cgp->cg_cs.cs_nbfree++;
fs->fs_cstotal.cs_nbfree++;
csum[cg].cs_nbfree++;
i = cbtocylno(fs, bno);
cg_blks(fs, cgp, i)[cbtorpos(fs, bno)]++;
cg_blktot(cgp)[i]++;
} else {
bbase = bno - fragnum(fs, bno);
/*
* decrement the counts associated with the old frags
*/
blk = blkmap(fs, cg_blksfree(cgp), bbase);
ffs_fragacct(fs, blk, cgp->cg_frsum, -1);
/*
* deallocate the fragment
*/
frags = numfrags(fs, size);
for (i = 0; i < frags; i++) {
assert (!isset (cg_blksfree(cgp), bno + i));
setbit(cg_blksfree(cgp), bno + i);
}
cgp->cg_cs.cs_nffree += i;
fs->fs_cstotal.cs_nffree += i;
csum[cg].cs_nffree += i;
/*
* add back in counts associated with the new frags
*/
blk = blkmap(fs, cg_blksfree(cgp), bbase);
ffs_fragacct(fs, blk, cgp->cg_frsum, 1);
/*
* if a complete block has been reassembled, account for it
*/
blkno = fragstoblks(fs, bbase);
if (ffs_isblock(fs, cg_blksfree(cgp), blkno)) {
cgp->cg_cs.cs_nffree -= fs->fs_frag;
fs->fs_cstotal.cs_nffree -= fs->fs_frag;
csum[cg].cs_nffree -= fs->fs_frag;
ffs_clusteracct(fs, cgp, blkno, 1);
cgp->cg_cs.cs_nbfree++;
fs->fs_cstotal.cs_nbfree++;
csum[cg].cs_nbfree++;
i = cbtocylno(fs, bbase);
cg_blks(fs, cgp, i)[cbtorpos(fs, bbase)]++;
cg_blktot(cgp)[i]++;
}
}
if (releasecg)
release_cg (cgp);
record_poke (cgp, sblock->fs_cgsize);
csum_dirty = 1;
sblock_dirty = 1;
fs->fs_fmod = 1;
alloc_sync (np);
/* bdwrite(bp); */
}
/*
* Free an inode.
*
* The specified inode is placed back in the free map.
*/
/* Implement diskfs call back diskfs_free_node (described in
<hurd/diskfs.h>. This was called ffs_vfree in BSD. */
void
diskfs_free_node (struct node *np, mode_t mode)
{
register struct fs *fs;
struct cg *cgp;
ino_t ino = np->dn->number;
int cg;
int releasecg;
fs = sblock;
assert (ino < fs->fs_ipg * fs->fs_ncg);
cg = ino_to_cg(fs, ino);
#if 0 /* Not this way in GNU Hurd ufs */
error = bread(pip->i_devvp, fsbtodb(fs, cgtod(fs, cg)),
(int)fs->fs_cgsize, NOCRED, &bp);
if (error) {
brelse(bp);
return (0);
}
cgp = (struct cg *)bp->b_data;
#else
releasecg = read_cg (cg, &cgp);
#endif
if (!cg_chkmagic(cgp)) {
/* brelse(bp); */
if (releasecg)
release_cg (cgp);
return;
}
cgp->cg_time = diskfs_mtime->seconds;
ino %= fs->fs_ipg;
if (isclr(cg_inosused(cgp), ino)) {
/* printf("dev = 0x%x, ino = %Ld, fs = %s\n",
pip->i_dev, ino, fs->fs_fsmnt); */
assert (diskfs_readonly);
}
clrbit(cg_inosused(cgp), ino);
if (ino < cgp->cg_irotor)
cgp->cg_irotor = ino;
cgp->cg_cs.cs_nifree++;
fs->fs_cstotal.cs_nifree++;
csum[cg].cs_nifree++;
if ((mode & IFMT) == IFDIR) {
cgp->cg_cs.cs_ndir--;
fs->fs_cstotal.cs_ndir--;
csum[cg].cs_ndir--;
}
if (releasecg)
release_cg (cgp);
record_poke (cgp, sblock->fs_cgsize);
csum_dirty = 1;
sblock_dirty = 1;
fs->fs_fmod = 1;
alloc_sync (np);
/* bdwrite(bp); */
}
/*
* Find a block of the specified size in the specified cylinder group.
*
* It is a panic if a request is made to find a block if none are
* available.
*/
static daddr_t
ffs_mapsearch(register struct fs *fs,
register struct cg *cgp,
daddr_t bpref,
int allocsiz)
{
daddr_t bno;
int start, len, loc, i;
int blk, field, subfield, pos;
/*
* find the fragment by searching through the free block
* map for an appropriate bit pattern
*/
if (bpref)
start = dtogd(fs, bpref) / NBBY;
else
start = cgp->cg_frotor / NBBY;
len = howmany(fs->fs_fpg, NBBY) - start;
loc = scanc((u_int)len, (u_char *)&cg_blksfree(cgp)[start],
(u_char *)fragtbl[fs->fs_frag],
(u_char)(1 << (allocsiz - 1 + (fs->fs_frag % NBBY))));
if (loc == 0) {
len = start + 1;
start = 0;
loc = scanc((u_int)len, (u_char *)&cg_blksfree(cgp)[0],
(u_char *)fragtbl[fs->fs_frag],
(u_char)(1 << (allocsiz - 1 + (fs->fs_frag % NBBY))));
assert (loc);
}
bno = (start + len - loc) * NBBY;
cgp->cg_frotor = bno;
/*
* found the byte in the map
* sift through the bits to find the selected frag
*/
for (i = bno + NBBY; bno < i; bno += fs->fs_frag) {
blk = blkmap(fs, cg_blksfree(cgp), bno);
blk <<= 1;
field = around[allocsiz];
subfield = inside[allocsiz];
for (pos = 0; pos <= fs->fs_frag - allocsiz; pos++) {
if ((blk & field) == subfield)
return (bno + pos);
field <<= 1;
subfield <<= 1;
}
}
assert (0);
return (-1);
}
/*
* Update the cluster map because of an allocation or free.
*
* Cnt == 1 means free; cnt == -1 means allocating.
*/
static void
ffs_clusteracct(struct fs *fs,
struct cg *cgp,
daddr_t blkno,
int cnt)
{
long *sump;
u_char *freemapp, *mapp;
int i, start, end, forw, back, map, bit;
if (fs->fs_contigsumsize <= 0)
return;
freemapp = cg_clustersfree(cgp);
sump = cg_clustersum(cgp);
/*
* Allocate or clear the actual block.
*/
if (cnt > 0)
setbit(freemapp, blkno);
else
clrbit(freemapp, blkno);
/*
* Find the size of the cluster going forward.
*/
start = blkno + 1;
end = start + fs->fs_contigsumsize;
if (end >= cgp->cg_nclusterblks)
end = cgp->cg_nclusterblks;
mapp = &freemapp[start / NBBY];
map = *mapp++;
bit = 1 << (start % NBBY);
for (i = start; i < end; i++) {
if ((map & bit) == 0)
break;
if ((i & (NBBY - 1)) != (NBBY - 1)) {
bit <<= 1;
} else {
map = *mapp++;
bit = 1;
}
}
forw = i - start;
/*
* Find the size of the cluster going backward.
*/
start = blkno - 1;
end = start - fs->fs_contigsumsize;
if (end < 0)
end = -1;
mapp = &freemapp[start / NBBY];
map = *mapp--;
bit = 1 << (start % NBBY);
for (i = start; i > end; i--) {
if ((map & bit) == 0)
break;
if ((i & (NBBY - 1)) != 0) {
bit >>= 1;
} else {
map = *mapp--;
bit = 1 << (NBBY - 1);
}
}
back = start - i;
/*
* Account for old cluster and the possibly new forward and
* back clusters.
*/
i = back + forw + 1;
if (i > fs->fs_contigsumsize)
i = fs->fs_contigsumsize;
sump[i] += cnt;
if (back > 0)
sump[back] -= cnt;
if (forw > 0)
sump[forw] -= cnt;
}
#if 0
/*
* Fserr prints the name of a file system with an error diagnostic.
*
* The form of the error message is:
* fs: error message
*/
static void
ffs_fserr(fs, uid, cp)
struct fs *fs;
u_int uid;
char *cp;
{
log(LOG_ERR, "uid %d on %s: %s\n", uid, fs->fs_fsmnt, cp);
}
#endif
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