freebsd-dev/sys/ufs/ffs/ffs_alloc.c
Kirk McKusick 6b9d4fbb7f Explicitly initialize rather than reading newly allocated UFS inodes.
The function ffs_vgetf() is used to find or load UFS inodes into a
vnode. It first looks up the inode and if found in the cache its
vnode is returned. If it is not already in the cache, a new vnode
is allocated and its associated inode read in from the disk. The
read is done even for inodes that are being initially created.
The contents for the inode on the disk are assumed to be empty. If
the on-disk contents had been corrupted either due to a hardware
glitch or an agent deliberately trying to exploit the system, the
UFS code could panic from the unexpected partially-allocated inode.

Rather then having fsck_ffs(8) verify that all unallocated inodes
are properly empty, it is easier and quicker to add a flag to
ffs_vgetf() to indicate that the request is for a newly allocated
inode. When set, the disk read is skipped and the inode is set to
its expected empty (zero'ed out) initial state. As a side benefit,
an unneeded disk I/O is avoided.

Reported by:  Peter Holm
Sponsored by: The FreeBSD Foundation
2022-08-13 13:51:25 -07:00

3505 lines
100 KiB
C

/*-
* SPDX-License-Identifier: (BSD-2-Clause-FreeBSD AND BSD-3-Clause)
*
* Copyright (c) 2002 Networks Associates Technology, Inc.
* All rights reserved.
*
* This software was developed for the FreeBSD Project by Marshall
* Kirk McKusick and Network Associates Laboratories, the Security
* Research Division of Network Associates, Inc. under DARPA/SPAWAR
* contract N66001-01-C-8035 ("CBOSS"), as part of the DARPA CHATS
* research program
*
* 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.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR 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 AUTHOR 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.
*
* 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. 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 8.18 (Berkeley) 5/26/95
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include "opt_quota.h"
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/bio.h>
#include <sys/buf.h>
#include <sys/capsicum.h>
#include <sys/conf.h>
#include <sys/fcntl.h>
#include <sys/file.h>
#include <sys/filedesc.h>
#include <sys/gsb_crc32.h>
#include <sys/kernel.h>
#include <sys/mount.h>
#include <sys/priv.h>
#include <sys/proc.h>
#include <sys/stat.h>
#include <sys/syscallsubr.h>
#include <sys/sysctl.h>
#include <sys/syslog.h>
#include <sys/taskqueue.h>
#include <sys/vnode.h>
#include <security/audit/audit.h>
#include <geom/geom.h>
#include <geom/geom_vfs.h>
#include <ufs/ufs/dir.h>
#include <ufs/ufs/extattr.h>
#include <ufs/ufs/quota.h>
#include <ufs/ufs/inode.h>
#include <ufs/ufs/ufs_extern.h>
#include <ufs/ufs/ufsmount.h>
#include <ufs/ffs/fs.h>
#include <ufs/ffs/ffs_extern.h>
#include <ufs/ffs/softdep.h>
typedef ufs2_daddr_t allocfcn_t(struct inode *ip, u_int cg, ufs2_daddr_t bpref,
int size, int rsize);
static ufs2_daddr_t ffs_alloccg(struct inode *, u_int, ufs2_daddr_t, int, int);
static ufs2_daddr_t
ffs_alloccgblk(struct inode *, struct buf *, ufs2_daddr_t, int);
static void ffs_blkfree_cg(struct ufsmount *, struct fs *,
struct vnode *, ufs2_daddr_t, long, ino_t,
struct workhead *);
#ifdef INVARIANTS
static int ffs_checkblk(struct inode *, ufs2_daddr_t, long);
#endif
static ufs2_daddr_t ffs_clusteralloc(struct inode *, u_int, ufs2_daddr_t, int);
static ino_t ffs_dirpref(struct inode *);
static ufs2_daddr_t ffs_fragextend(struct inode *, u_int, ufs2_daddr_t,
int, int);
static ufs2_daddr_t ffs_hashalloc
(struct inode *, u_int, ufs2_daddr_t, int, int, allocfcn_t *);
static ufs2_daddr_t ffs_nodealloccg(struct inode *, u_int, ufs2_daddr_t, int,
int);
static ufs1_daddr_t ffs_mapsearch(struct fs *, struct cg *, ufs2_daddr_t, int);
static int ffs_reallocblks_ufs1(struct vop_reallocblks_args *);
static int ffs_reallocblks_ufs2(struct vop_reallocblks_args *);
static void ffs_ckhash_cg(struct buf *);
/*
* Allocate a block in the filesystem.
*
* 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) quadratically rehash into other cylinder groups, until an
* available block is located.
* If no block preference is given the following hierarchy is used
* to allocate a block:
* 1) allocate a block in the cylinder group that contains the
* inode for the file.
* 2) quadratically rehash into other cylinder groups, until an
* available block is located.
*/
int
ffs_alloc(struct inode *ip,
ufs2_daddr_t lbn,
ufs2_daddr_t bpref,
int size,
int flags,
struct ucred *cred,
ufs2_daddr_t *bnp)
{
struct fs *fs;
struct ufsmount *ump;
ufs2_daddr_t bno;
u_int cg, reclaimed;
int64_t delta;
#ifdef QUOTA
int error;
#endif
*bnp = 0;
ump = ITOUMP(ip);
fs = ump->um_fs;
mtx_assert(UFS_MTX(ump), MA_OWNED);
#ifdef INVARIANTS
if ((u_int)size > fs->fs_bsize || fragoff(fs, size) != 0) {
printf("dev = %s, bsize = %ld, size = %d, fs = %s\n",
devtoname(ump->um_dev), (long)fs->fs_bsize, size,
fs->fs_fsmnt);
panic("ffs_alloc: bad size");
}
if (cred == NOCRED)
panic("ffs_alloc: missing credential");
#endif /* INVARIANTS */
reclaimed = 0;
retry:
#ifdef QUOTA
UFS_UNLOCK(ump);
error = chkdq(ip, btodb(size), cred, 0);
if (error)
return (error);
UFS_LOCK(ump);
#endif
if (size == fs->fs_bsize && fs->fs_cstotal.cs_nbfree == 0)
goto nospace;
if (priv_check_cred(cred, PRIV_VFS_BLOCKRESERVE) &&
freespace(fs, fs->fs_minfree) - numfrags(fs, size) < 0)
goto nospace;
if (bpref >= fs->fs_size)
bpref = 0;
if (bpref == 0)
cg = ino_to_cg(fs, ip->i_number);
else
cg = dtog(fs, bpref);
bno = ffs_hashalloc(ip, cg, bpref, size, size, ffs_alloccg);
if (bno > 0) {
delta = btodb(size);
DIP_SET(ip, i_blocks, DIP(ip, i_blocks) + delta);
if (flags & IO_EXT)
UFS_INODE_SET_FLAG(ip, IN_CHANGE);
else
UFS_INODE_SET_FLAG(ip, IN_CHANGE | IN_UPDATE);
*bnp = bno;
return (0);
}
nospace:
#ifdef QUOTA
UFS_UNLOCK(ump);
/*
* Restore user's disk quota because allocation failed.
*/
(void) chkdq(ip, -btodb(size), cred, FORCE);
UFS_LOCK(ump);
#endif
if (reclaimed == 0 && (flags & IO_BUFLOCKED) == 0) {
reclaimed = 1;
softdep_request_cleanup(fs, ITOV(ip), cred, FLUSH_BLOCKS_WAIT);
goto retry;
}
if (ffs_fsfail_cleanup_locked(ump, 0)) {
UFS_UNLOCK(ump);
return (ENXIO);
}
if (reclaimed > 0 &&
ppsratecheck(&ump->um_last_fullmsg, &ump->um_secs_fullmsg, 1)) {
UFS_UNLOCK(ump);
ffs_fserr(fs, ip->i_number, "filesystem full");
uprintf("\n%s: write failed, filesystem is full\n",
fs->fs_fsmnt);
} else {
UFS_UNLOCK(ump);
}
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.
*/
int
ffs_realloccg(struct inode *ip,
ufs2_daddr_t lbprev,
ufs2_daddr_t bprev,
ufs2_daddr_t bpref,
int osize,
int nsize,
int flags,
struct ucred *cred,
struct buf **bpp)
{
struct vnode *vp;
struct fs *fs;
struct buf *bp;
struct ufsmount *ump;
u_int cg, request, reclaimed;
int error, gbflags;
ufs2_daddr_t bno;
int64_t delta;
vp = ITOV(ip);
ump = ITOUMP(ip);
fs = ump->um_fs;
bp = NULL;
gbflags = (flags & BA_UNMAPPED) != 0 ? GB_UNMAPPED : 0;
#ifdef WITNESS
gbflags |= IS_SNAPSHOT(ip) ? GB_NOWITNESS : 0;
#endif
mtx_assert(UFS_MTX(ump), MA_OWNED);
#ifdef INVARIANTS
if (vp->v_mount->mnt_kern_flag & MNTK_SUSPENDED)
panic("ffs_realloccg: allocation on suspended filesystem");
if ((u_int)osize > fs->fs_bsize || fragoff(fs, osize) != 0 ||
(u_int)nsize > fs->fs_bsize || fragoff(fs, nsize) != 0) {
printf(
"dev = %s, bsize = %ld, osize = %d, nsize = %d, fs = %s\n",
devtoname(ump->um_dev), (long)fs->fs_bsize, osize,
nsize, fs->fs_fsmnt);
panic("ffs_realloccg: bad size");
}
if (cred == NOCRED)
panic("ffs_realloccg: missing credential");
#endif /* INVARIANTS */
reclaimed = 0;
retry:
if (priv_check_cred(cred, PRIV_VFS_BLOCKRESERVE) &&
freespace(fs, fs->fs_minfree) - numfrags(fs, nsize - osize) < 0) {
goto nospace;
}
if (bprev == 0) {
printf("dev = %s, bsize = %ld, bprev = %jd, fs = %s\n",
devtoname(ump->um_dev), (long)fs->fs_bsize, (intmax_t)bprev,
fs->fs_fsmnt);
panic("ffs_realloccg: bad bprev");
}
UFS_UNLOCK(ump);
/*
* Allocate the extra space in the buffer.
*/
error = bread_gb(vp, lbprev, osize, NOCRED, gbflags, &bp);
if (error) {
return (error);
}
if (bp->b_blkno == bp->b_lblkno) {
if (lbprev >= UFS_NDADDR)
panic("ffs_realloccg: lbprev out of range");
bp->b_blkno = fsbtodb(fs, bprev);
}
#ifdef QUOTA
error = chkdq(ip, btodb(nsize - osize), cred, 0);
if (error) {
brelse(bp);
return (error);
}
#endif
/*
* Check for extension in the existing location.
*/
*bpp = NULL;
cg = dtog(fs, bprev);
UFS_LOCK(ump);
bno = ffs_fragextend(ip, cg, bprev, osize, nsize);
if (bno) {
if (bp->b_blkno != fsbtodb(fs, bno))
panic("ffs_realloccg: bad blockno");
delta = btodb(nsize - osize);
DIP_SET(ip, i_blocks, DIP(ip, i_blocks) + delta);
if (flags & IO_EXT)
UFS_INODE_SET_FLAG(ip, IN_CHANGE);
else
UFS_INODE_SET_FLAG(ip, IN_CHANGE | IN_UPDATE);
allocbuf(bp, nsize);
bp->b_flags |= B_DONE;
vfs_bio_bzero_buf(bp, osize, nsize - osize);
if ((bp->b_flags & (B_MALLOC | B_VMIO)) == B_VMIO)
vfs_bio_set_valid(bp, osize, nsize - osize);
*bpp = bp;
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 >
(off_t)fs->fs_dsize * fs->fs_minfree / (2 * 100))
break;
log(LOG_NOTICE, "%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 <
(off_t)fs->fs_dsize * (fs->fs_minfree - 2) / 100)
break;
log(LOG_NOTICE, "%s: optimization changed from TIME to SPACE\n",
fs->fs_fsmnt);
fs->fs_optim = FS_OPTSPACE;
break;
default:
printf("dev = %s, optim = %ld, fs = %s\n",
devtoname(ump->um_dev), (long)fs->fs_optim, fs->fs_fsmnt);
panic("ffs_realloccg: bad optim");
/* NOTREACHED */
}
bno = ffs_hashalloc(ip, cg, bpref, request, nsize, ffs_alloccg);
if (bno > 0) {
bp->b_blkno = fsbtodb(fs, bno);
if (!DOINGSOFTDEP(vp))
/*
* The usual case is that a smaller fragment that
* was just allocated has been replaced with a bigger
* fragment or a full-size block. If it is marked as
* B_DELWRI, the current contents have not been written
* to disk. It is possible that the block was written
* earlier, but very uncommon. If the block has never
* been written, there is no need to send a BIO_DELETE
* for it when it is freed. The gain from avoiding the
* TRIMs for the common case of unwritten blocks far
* exceeds the cost of the write amplification for the
* uncommon case of failing to send a TRIM for a block
* that had been written.
*/
ffs_blkfree(ump, fs, ump->um_devvp, bprev, (long)osize,
ip->i_number, vp->v_type, NULL,
(bp->b_flags & B_DELWRI) != 0 ?
NOTRIM_KEY : SINGLETON_KEY);
delta = btodb(nsize - osize);
DIP_SET(ip, i_blocks, DIP(ip, i_blocks) + delta);
if (flags & IO_EXT)
UFS_INODE_SET_FLAG(ip, IN_CHANGE);
else
UFS_INODE_SET_FLAG(ip, IN_CHANGE | IN_UPDATE);
allocbuf(bp, nsize);
bp->b_flags |= B_DONE;
vfs_bio_bzero_buf(bp, osize, nsize - osize);
if ((bp->b_flags & (B_MALLOC | B_VMIO)) == B_VMIO)
vfs_bio_set_valid(bp, osize, nsize - osize);
*bpp = bp;
return (0);
}
#ifdef QUOTA
UFS_UNLOCK(ump);
/*
* Restore user's disk quota because allocation failed.
*/
(void) chkdq(ip, -btodb(nsize - osize), cred, FORCE);
UFS_LOCK(ump);
#endif
nospace:
/*
* no space available
*/
if (reclaimed == 0 && (flags & IO_BUFLOCKED) == 0) {
reclaimed = 1;
UFS_UNLOCK(ump);
if (bp) {
brelse(bp);
bp = NULL;
}
UFS_LOCK(ump);
softdep_request_cleanup(fs, vp, cred, FLUSH_BLOCKS_WAIT);
goto retry;
}
if (bp)
brelse(bp);
if (ffs_fsfail_cleanup_locked(ump, 0)) {
UFS_UNLOCK(ump);
return (ENXIO);
}
if (reclaimed > 0 &&
ppsratecheck(&ump->um_last_fullmsg, &ump->um_secs_fullmsg, 1)) {
UFS_UNLOCK(ump);
ffs_fserr(fs, ip->i_number, "filesystem full");
uprintf("\n%s: write failed, filesystem is full\n",
fs->fs_fsmnt);
} else {
UFS_UNLOCK(ump);
}
return (ENOSPC);
}
/*
* 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
* from the end of the allocation for the logical block immediately
* preceding 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.
*/
SYSCTL_NODE(_vfs, OID_AUTO, ffs, CTLFLAG_RW | CTLFLAG_MPSAFE, 0,
"FFS filesystem");
static int doasyncfree = 1;
SYSCTL_INT(_vfs_ffs, OID_AUTO, doasyncfree, CTLFLAG_RW, &doasyncfree, 0,
"do not force synchronous writes when blocks are reallocated");
static int doreallocblks = 1;
SYSCTL_INT(_vfs_ffs, OID_AUTO, doreallocblks, CTLFLAG_RW, &doreallocblks, 0,
"enable block reallocation");
static int dotrimcons = 1;
SYSCTL_INT(_vfs_ffs, OID_AUTO, dotrimcons, CTLFLAG_RWTUN, &dotrimcons, 0,
"enable BIO_DELETE / TRIM consolidation");
static int maxclustersearch = 10;
SYSCTL_INT(_vfs_ffs, OID_AUTO, maxclustersearch, CTLFLAG_RW, &maxclustersearch,
0, "max number of cylinder group to search for contigous blocks");
#ifdef DIAGNOSTIC
static int prtrealloc = 0;
SYSCTL_INT(_debug, OID_AUTO, ffs_prtrealloc, CTLFLAG_RW, &prtrealloc, 0,
"print out FFS filesystem block reallocation operations");
#endif
int
ffs_reallocblks(
struct vop_reallocblks_args /* {
struct vnode *a_vp;
struct cluster_save *a_buflist;
} */ *ap)
{
struct ufsmount *ump;
int error;
/*
* We used to skip reallocating the blocks of a file into a
* contiguous sequence if the underlying flash device requested
* BIO_DELETE notifications, because devices that benefit from
* BIO_DELETE also benefit from not moving the data. However,
* the destination for the data is usually moved before the data
* is written to the initially allocated location, so we rarely
* suffer the penalty of extra writes. With the addition of the
* consolidation of contiguous blocks into single BIO_DELETE
* operations, having fewer but larger contiguous blocks reduces
* the number of (slow and expensive) BIO_DELETE operations. So
* when doing BIO_DELETE consolidation, we do block reallocation.
*
* Skip if reallocblks has been disabled globally.
*/
ump = ap->a_vp->v_mount->mnt_data;
if ((((ump->um_flags) & UM_CANDELETE) != 0 && dotrimcons == 0) ||
doreallocblks == 0)
return (ENOSPC);
/*
* We can't wait in softdep prealloc as it may fsync and recurse
* here. Instead we simply fail to reallocate blocks if this
* rare condition arises.
*/
if (DOINGSUJ(ap->a_vp))
if (softdep_prealloc(ap->a_vp, MNT_NOWAIT) != 0)
return (ENOSPC);
vn_seqc_write_begin(ap->a_vp);
error = ump->um_fstype == UFS1 ? ffs_reallocblks_ufs1(ap) :
ffs_reallocblks_ufs2(ap);
vn_seqc_write_end(ap->a_vp);
return (error);
}
static int
ffs_reallocblks_ufs1(
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, *bp;
ufs1_daddr_t *bap, *sbap, *ebap;
struct cluster_save *buflist;
struct ufsmount *ump;
ufs_lbn_t start_lbn, end_lbn;
ufs1_daddr_t soff, newblk, blkno;
ufs2_daddr_t pref;
struct indir start_ap[UFS_NIADDR + 1], end_ap[UFS_NIADDR + 1], *idp;
int i, cg, len, start_lvl, end_lvl, ssize;
vp = ap->a_vp;
ip = VTOI(vp);
ump = ITOUMP(ip);
fs = ump->um_fs;
/*
* If we are not tracking block clusters or if we have less than 4%
* free blocks left, then do not attempt to cluster. Running with
* less than 5% free block reserve is not recommended and those that
* choose to do so do not expect to have good file layout.
*/
if (fs->fs_contigsumsize <= 0 || freespace(fs, 4) < 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 INVARIANTS
for (i = 0; i < len; i++)
if (!ffs_checkblk(ip,
dbtofsb(fs, buflist->bs_children[i]->b_blkno), fs->fs_bsize))
panic("ffs_reallocblks: unallocated block 1");
for (i = 1; i < len; i++)
if (buflist->bs_children[i]->b_lblkno != start_lbn + i)
panic("ffs_reallocblks: non-logical cluster");
blkno = buflist->bs_children[0]->b_blkno;
ssize = fsbtodb(fs, fs->fs_frag);
for (i = 1; i < len - 1; i++)
if (buflist->bs_children[i]->b_blkno != blkno + (i * ssize))
panic("ffs_reallocblks: non-physical cluster %d", i);
#endif
/*
* If the cluster crosses the boundary for the first indirect
* block, leave space for the indirect block. Indirect blocks
* are initially laid out in a position after the last direct
* block. Block reallocation would usually destroy locality by
* moving the indirect block out of the way to make room for
* data blocks if we didn't compensate here. We should also do
* this for other indirect block boundaries, but it is only
* important for the first one.
*/
if (start_lbn < UFS_NDADDR && end_lbn >= UFS_NDADDR)
return (ENOSPC);
/*
* 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_din1->di_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 = (ufs1_daddr_t *)sbp->b_data;
soff = idp->in_off;
}
/*
* If the block range spans two block maps, get the second map.
*/
ebap = NULL;
if (end_lvl == 0 || (idp = &end_ap[end_lvl - 1])->in_off + 1 >= len) {
ssize = len;
} else {
#ifdef INVARIANTS
if (start_lvl > 0 &&
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 = (ufs1_daddr_t *)ebp->b_data;
}
/*
* Find the preferred location for the cluster. If we have not
* previously failed at this endeavor, then follow our standard
* preference calculation. If we have failed at it, then pick up
* where we last ended our search.
*/
UFS_LOCK(ump);
if (ip->i_nextclustercg == -1)
pref = ffs_blkpref_ufs1(ip, start_lbn, soff, sbap);
else
pref = cgdata(fs, ip->i_nextclustercg);
/*
* Search the block map looking for an allocation of the desired size.
* To avoid wasting too much time, we limit the number of cylinder
* groups that we will search.
*/
cg = dtog(fs, pref);
for (i = min(maxclustersearch, fs->fs_ncg); i > 0; i--) {
if ((newblk = ffs_clusteralloc(ip, cg, pref, len)) != 0)
break;
cg += 1;
if (cg >= fs->fs_ncg)
cg = 0;
}
/*
* If we have failed in our search, record where we gave up for
* next time. Otherwise, fall back to our usual search citerion.
*/
if (newblk == 0) {
ip->i_nextclustercg = cg;
UFS_UNLOCK(ump);
goto fail;
}
ip->i_nextclustercg = -1;
/*
* 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.
*/
#ifdef DIAGNOSTIC
if (prtrealloc)
printf("realloc: ino %ju, lbns %jd-%jd\n\told:",
(uintmax_t)ip->i_number,
(intmax_t)start_lbn, (intmax_t)end_lbn);
#endif
blkno = newblk;
for (bap = &sbap[soff], i = 0; i < len; i++, blkno += fs->fs_frag) {
if (i == ssize) {
bap = ebap;
soff = -i;
}
#ifdef INVARIANTS
if (!ffs_checkblk(ip,
dbtofsb(fs, buflist->bs_children[i]->b_blkno), fs->fs_bsize))
panic("ffs_reallocblks: unallocated block 2");
if (dbtofsb(fs, buflist->bs_children[i]->b_blkno) != *bap)
panic("ffs_reallocblks: alloc mismatch");
#endif
#ifdef DIAGNOSTIC
if (prtrealloc)
printf(" %d,", *bap);
#endif
if (DOINGSOFTDEP(vp)) {
if (sbap == &ip->i_din1->di_db[0] && i < ssize)
softdep_setup_allocdirect(ip, start_lbn + i,
blkno, *bap, fs->fs_bsize, fs->fs_bsize,
buflist->bs_children[i]);
else
softdep_setup_allocindir_page(ip, start_lbn + i,
i < ssize ? sbp : ebp, soff + i, blkno,
*bap, buflist->bs_children[i]);
}
*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_din1->di_db[0]) {
if (doasyncfree)
bdwrite(sbp);
else
bwrite(sbp);
} else {
UFS_INODE_SET_FLAG(ip, IN_CHANGE | IN_UPDATE);
if (!doasyncfree)
ffs_update(vp, 1);
}
if (ssize < len) {
if (doasyncfree)
bdwrite(ebp);
else
bwrite(ebp);
}
/*
* Last, free the old blocks and assign the new blocks to the buffers.
*/
#ifdef DIAGNOSTIC
if (prtrealloc)
printf("\n\tnew:");
#endif
for (blkno = newblk, i = 0; i < len; i++, blkno += fs->fs_frag) {
bp = buflist->bs_children[i];
if (!DOINGSOFTDEP(vp))
/*
* The usual case is that a set of N-contiguous blocks
* that was just allocated has been replaced with a
* set of N+1-contiguous blocks. If they are marked as
* B_DELWRI, the current contents have not been written
* to disk. It is possible that the blocks were written
* earlier, but very uncommon. If the blocks have never
* been written, there is no need to send a BIO_DELETE
* for them when they are freed. The gain from avoiding
* the TRIMs for the common case of unwritten blocks
* far exceeds the cost of the write amplification for
* the uncommon case of failing to send a TRIM for the
* blocks that had been written.
*/
ffs_blkfree(ump, fs, ump->um_devvp,
dbtofsb(fs, bp->b_blkno),
fs->fs_bsize, ip->i_number, vp->v_type, NULL,
(bp->b_flags & B_DELWRI) != 0 ?
NOTRIM_KEY : SINGLETON_KEY);
bp->b_blkno = fsbtodb(fs, blkno);
#ifdef INVARIANTS
if (!ffs_checkblk(ip, dbtofsb(fs, bp->b_blkno), fs->fs_bsize))
panic("ffs_reallocblks: unallocated block 3");
#endif
#ifdef DIAGNOSTIC
if (prtrealloc)
printf(" %d,", blkno);
#endif
}
#ifdef DIAGNOSTIC
if (prtrealloc) {
prtrealloc--;
printf("\n");
}
#endif
return (0);
fail:
if (ssize < len)
brelse(ebp);
if (sbap != &ip->i_din1->di_db[0])
brelse(sbp);
return (ENOSPC);
}
static int
ffs_reallocblks_ufs2(
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, *bp;
ufs2_daddr_t *bap, *sbap, *ebap;
struct cluster_save *buflist;
struct ufsmount *ump;
ufs_lbn_t start_lbn, end_lbn;
ufs2_daddr_t soff, newblk, blkno, pref;
struct indir start_ap[UFS_NIADDR + 1], end_ap[UFS_NIADDR + 1], *idp;
int i, cg, len, start_lvl, end_lvl, ssize;
vp = ap->a_vp;
ip = VTOI(vp);
ump = ITOUMP(ip);
fs = ump->um_fs;
/*
* If we are not tracking block clusters or if we have less than 4%
* free blocks left, then do not attempt to cluster. Running with
* less than 5% free block reserve is not recommended and those that
* choose to do so do not expect to have good file layout.
*/
if (fs->fs_contigsumsize <= 0 || freespace(fs, 4) < 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 INVARIANTS
for (i = 0; i < len; i++)
if (!ffs_checkblk(ip,
dbtofsb(fs, buflist->bs_children[i]->b_blkno), fs->fs_bsize))
panic("ffs_reallocblks: unallocated block 1");
for (i = 1; i < len; i++)
if (buflist->bs_children[i]->b_lblkno != start_lbn + i)
panic("ffs_reallocblks: non-logical cluster");
blkno = buflist->bs_children[0]->b_blkno;
ssize = fsbtodb(fs, fs->fs_frag);
for (i = 1; i < len - 1; i++)
if (buflist->bs_children[i]->b_blkno != blkno + (i * ssize))
panic("ffs_reallocblks: non-physical cluster %d", i);
#endif
/*
* If the cluster crosses the boundary for the first indirect
* block, do not move anything in it. Indirect blocks are
* usually initially laid out in a position between the data
* blocks. Block reallocation would usually destroy locality by
* moving the indirect block out of the way to make room for
* data blocks if we didn't compensate here. We should also do
* this for other indirect block boundaries, but it is only
* important for the first one.
*/
if (start_lbn < UFS_NDADDR && end_lbn >= UFS_NDADDR)
return (ENOSPC);
/*
* 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_din2->di_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 = (ufs2_daddr_t *)sbp->b_data;
soff = idp->in_off;
}
/*
* If the block range spans two block maps, get the second map.
*/
ebap = NULL;
if (end_lvl == 0 || (idp = &end_ap[end_lvl - 1])->in_off + 1 >= len) {
ssize = len;
} else {
#ifdef INVARIANTS
if (start_lvl > 0 &&
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 = (ufs2_daddr_t *)ebp->b_data;
}
/*
* Find the preferred location for the cluster. If we have not
* previously failed at this endeavor, then follow our standard
* preference calculation. If we have failed at it, then pick up
* where we last ended our search.
*/
UFS_LOCK(ump);
if (ip->i_nextclustercg == -1)
pref = ffs_blkpref_ufs2(ip, start_lbn, soff, sbap);
else
pref = cgdata(fs, ip->i_nextclustercg);
/*
* Search the block map looking for an allocation of the desired size.
* To avoid wasting too much time, we limit the number of cylinder
* groups that we will search.
*/
cg = dtog(fs, pref);
for (i = min(maxclustersearch, fs->fs_ncg); i > 0; i--) {
if ((newblk = ffs_clusteralloc(ip, cg, pref, len)) != 0)
break;
cg += 1;
if (cg >= fs->fs_ncg)
cg = 0;
}
/*
* If we have failed in our search, record where we gave up for
* next time. Otherwise, fall back to our usual search citerion.
*/
if (newblk == 0) {
ip->i_nextclustercg = cg;
UFS_UNLOCK(ump);
goto fail;
}
ip->i_nextclustercg = -1;
/*
* 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.
*/
#ifdef DIAGNOSTIC
if (prtrealloc)
printf("realloc: ino %ju, lbns %jd-%jd\n\told:", (uintmax_t)ip->i_number,
(intmax_t)start_lbn, (intmax_t)end_lbn);
#endif
blkno = newblk;
for (bap = &sbap[soff], i = 0; i < len; i++, blkno += fs->fs_frag) {
if (i == ssize) {
bap = ebap;
soff = -i;
}
#ifdef INVARIANTS
if (!ffs_checkblk(ip,
dbtofsb(fs, buflist->bs_children[i]->b_blkno), fs->fs_bsize))
panic("ffs_reallocblks: unallocated block 2");
if (dbtofsb(fs, buflist->bs_children[i]->b_blkno) != *bap)
panic("ffs_reallocblks: alloc mismatch");
#endif
#ifdef DIAGNOSTIC
if (prtrealloc)
printf(" %jd,", (intmax_t)*bap);
#endif
if (DOINGSOFTDEP(vp)) {
if (sbap == &ip->i_din2->di_db[0] && i < ssize)
softdep_setup_allocdirect(ip, start_lbn + i,
blkno, *bap, fs->fs_bsize, fs->fs_bsize,
buflist->bs_children[i]);
else
softdep_setup_allocindir_page(ip, start_lbn + i,
i < ssize ? sbp : ebp, soff + i, blkno,
*bap, buflist->bs_children[i]);
}
*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_din2->di_db[0]) {
if (doasyncfree)
bdwrite(sbp);
else
bwrite(sbp);
} else {
UFS_INODE_SET_FLAG(ip, IN_CHANGE | IN_UPDATE);
if (!doasyncfree)
ffs_update(vp, 1);
}
if (ssize < len) {
if (doasyncfree)
bdwrite(ebp);
else
bwrite(ebp);
}
/*
* Last, free the old blocks and assign the new blocks to the buffers.
*/
#ifdef DIAGNOSTIC
if (prtrealloc)
printf("\n\tnew:");
#endif
for (blkno = newblk, i = 0; i < len; i++, blkno += fs->fs_frag) {
bp = buflist->bs_children[i];
if (!DOINGSOFTDEP(vp))
/*
* The usual case is that a set of N-contiguous blocks
* that was just allocated has been replaced with a
* set of N+1-contiguous blocks. If they are marked as
* B_DELWRI, the current contents have not been written
* to disk. It is possible that the blocks were written
* earlier, but very uncommon. If the blocks have never
* been written, there is no need to send a BIO_DELETE
* for them when they are freed. The gain from avoiding
* the TRIMs for the common case of unwritten blocks
* far exceeds the cost of the write amplification for
* the uncommon case of failing to send a TRIM for the
* blocks that had been written.
*/
ffs_blkfree(ump, fs, ump->um_devvp,
dbtofsb(fs, bp->b_blkno),
fs->fs_bsize, ip->i_number, vp->v_type, NULL,
(bp->b_flags & B_DELWRI) != 0 ?
NOTRIM_KEY : SINGLETON_KEY);
bp->b_blkno = fsbtodb(fs, blkno);
#ifdef INVARIANTS
if (!ffs_checkblk(ip, dbtofsb(fs, bp->b_blkno), fs->fs_bsize))
panic("ffs_reallocblks: unallocated block 3");
#endif
#ifdef DIAGNOSTIC
if (prtrealloc)
printf(" %jd,", (intmax_t)blkno);
#endif
}
#ifdef DIAGNOSTIC
if (prtrealloc) {
prtrealloc--;
printf("\n");
}
#endif
return (0);
fail:
if (ssize < len)
brelse(ebp);
if (sbap != &ip->i_din2->di_db[0])
brelse(sbp);
return (ENOSPC);
}
/*
* Allocate an inode in the filesystem.
*
* 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) quadratically rehash into other cylinder groups, until an
* available inode is located.
* If no inode preference is given the following hierarchy is used
* to allocate an inode:
* 1) allocate an inode in cylinder group 0.
* 2) quadratically rehash into other cylinder groups, until an
* available inode is located.
*/
int
ffs_valloc(struct vnode *pvp,
int mode,
struct ucred *cred,
struct vnode **vpp)
{
struct inode *pip;
struct fs *fs;
struct inode *ip;
struct timespec ts;
struct ufsmount *ump;
ino_t ino, ipref;
u_int cg;
int error, reclaimed;
*vpp = NULL;
pip = VTOI(pvp);
ump = ITOUMP(pip);
fs = ump->um_fs;
UFS_LOCK(ump);
reclaimed = 0;
retry:
if (fs->fs_cstotal.cs_nifree == 0)
goto noinodes;
if ((mode & IFMT) == IFDIR)
ipref = ffs_dirpref(pip);
else
ipref = pip->i_number;
if (ipref >= fs->fs_ncg * fs->fs_ipg)
ipref = 0;
cg = ino_to_cg(fs, ipref);
/*
* Track number of dirs created one after another
* in a same cg without intervening by files.
*/
if ((mode & IFMT) == IFDIR) {
if (fs->fs_contigdirs[cg] < 255)
fs->fs_contigdirs[cg]++;
} else {
if (fs->fs_contigdirs[cg] > 0)
fs->fs_contigdirs[cg]--;
}
ino = (ino_t)ffs_hashalloc(pip, cg, ipref, mode, 0,
(allocfcn_t *)ffs_nodealloccg);
if (ino == 0)
goto noinodes;
/*
* Get rid of the cached old vnode, force allocation of a new vnode
* for this inode. If this fails, release the allocated ino and
* return the error.
*/
if ((error = ffs_vgetf(pvp->v_mount, ino, LK_EXCLUSIVE, vpp,
FFSV_FORCEINSMQ | FFSV_REPLACE | FFSV_NEWINODE)) != 0) {
ffs_vfree(pvp, ino, mode);
return (error);
}
/*
* We got an inode, so check mode and panic if it is already allocated.
*/
ip = VTOI(*vpp);
if (ip->i_mode) {
printf("mode = 0%o, inum = %ju, fs = %s\n",
ip->i_mode, (uintmax_t)ip->i_number, fs->fs_fsmnt);
panic("ffs_valloc: dup alloc");
}
if (DIP(ip, i_blocks) && (fs->fs_flags & FS_UNCLEAN) == 0) { /* XXX */
printf("free inode %s/%lu had %ld blocks\n",
fs->fs_fsmnt, (u_long)ino, (long)DIP(ip, i_blocks));
DIP_SET(ip, i_blocks, 0);
}
ip->i_flags = 0;
DIP_SET(ip, i_flags, 0);
/*
* Set up a new generation number for this inode.
*/
while (ip->i_gen == 0 || ++ip->i_gen == 0)
ip->i_gen = arc4random();
DIP_SET(ip, i_gen, ip->i_gen);
if (fs->fs_magic == FS_UFS2_MAGIC) {
vfs_timestamp(&ts);
ip->i_din2->di_birthtime = ts.tv_sec;
ip->i_din2->di_birthnsec = ts.tv_nsec;
}
ip->i_flag = 0;
(*vpp)->v_vflag = 0;
(*vpp)->v_type = VNON;
if (fs->fs_magic == FS_UFS2_MAGIC) {
(*vpp)->v_op = &ffs_vnodeops2;
UFS_INODE_SET_FLAG(ip, IN_UFS2);
} else {
(*vpp)->v_op = &ffs_vnodeops1;
}
return (0);
noinodes:
if (reclaimed == 0) {
reclaimed = 1;
softdep_request_cleanup(fs, pvp, cred, FLUSH_INODES_WAIT);
goto retry;
}
if (ffs_fsfail_cleanup_locked(ump, 0)) {
UFS_UNLOCK(ump);
return (ENXIO);
}
if (ppsratecheck(&ump->um_last_fullmsg, &ump->um_secs_fullmsg, 1)) {
UFS_UNLOCK(ump);
ffs_fserr(fs, pip->i_number, "out of inodes");
uprintf("\n%s: create/symlink failed, no inodes free\n",
fs->fs_fsmnt);
} else {
UFS_UNLOCK(ump);
}
return (ENOSPC);
}
/*
* Find a cylinder group to place a directory.
*
* The policy implemented by this algorithm is to allocate a
* directory inode in the same cylinder group as its parent
* directory, but also to reserve space for its files inodes
* and data. Restrict the number of directories which may be
* allocated one after another in the same cylinder group
* without intervening allocation of files.
*
* If we allocate a first level directory then force allocation
* in another cylinder group.
*/
static ino_t
ffs_dirpref(struct inode *pip)
{
struct fs *fs;
int cg, prefcg, dirsize, cgsize;
u_int avgifree, avgbfree, avgndir, curdirsize;
u_int minifree, minbfree, maxndir;
u_int mincg, minndir;
u_int maxcontigdirs;
mtx_assert(UFS_MTX(ITOUMP(pip)), MA_OWNED);
fs = ITOFS(pip);
avgifree = fs->fs_cstotal.cs_nifree / fs->fs_ncg;
avgbfree = fs->fs_cstotal.cs_nbfree / fs->fs_ncg;
avgndir = fs->fs_cstotal.cs_ndir / fs->fs_ncg;
/*
* Force allocation in another cg if creating a first level dir.
*/
ASSERT_VOP_LOCKED(ITOV(pip), "ffs_dirpref");
if (ITOV(pip)->v_vflag & VV_ROOT) {
prefcg = arc4random() % fs->fs_ncg;
mincg = prefcg;
minndir = fs->fs_ipg;
for (cg = prefcg; cg < fs->fs_ncg; cg++)
if (fs->fs_cs(fs, cg).cs_ndir < minndir &&
fs->fs_cs(fs, cg).cs_nifree >= avgifree &&
fs->fs_cs(fs, cg).cs_nbfree >= avgbfree) {
mincg = cg;
minndir = fs->fs_cs(fs, cg).cs_ndir;
}
for (cg = 0; cg < prefcg; cg++)
if (fs->fs_cs(fs, cg).cs_ndir < minndir &&
fs->fs_cs(fs, cg).cs_nifree >= avgifree &&
fs->fs_cs(fs, cg).cs_nbfree >= avgbfree) {
mincg = cg;
minndir = fs->fs_cs(fs, cg).cs_ndir;
}
return ((ino_t)(fs->fs_ipg * mincg));
}
/*
* Count various limits which used for
* optimal allocation of a directory inode.
*/
maxndir = min(avgndir + fs->fs_ipg / 16, fs->fs_ipg);
minifree = avgifree - avgifree / 4;
if (minifree < 1)
minifree = 1;
minbfree = avgbfree - avgbfree / 4;
if (minbfree < 1)
minbfree = 1;
cgsize = fs->fs_fsize * fs->fs_fpg;
dirsize = fs->fs_avgfilesize * fs->fs_avgfpdir;
curdirsize = avgndir ? (cgsize - avgbfree * fs->fs_bsize) / avgndir : 0;
if (dirsize < curdirsize)
dirsize = curdirsize;
if (dirsize <= 0)
maxcontigdirs = 0; /* dirsize overflowed */
else
maxcontigdirs = min((avgbfree * fs->fs_bsize) / dirsize, 255);
if (fs->fs_avgfpdir > 0)
maxcontigdirs = min(maxcontigdirs,
fs->fs_ipg / fs->fs_avgfpdir);
if (maxcontigdirs == 0)
maxcontigdirs = 1;
/*
* Limit number of dirs in one cg and reserve space for
* regular files, but only if we have no deficit in
* inodes or space.
*
* We are trying to find a suitable cylinder group nearby
* our preferred cylinder group to place a new directory.
* We scan from our preferred cylinder group forward looking
* for a cylinder group that meets our criterion. If we get
* to the final cylinder group and do not find anything,
* we start scanning forwards from the beginning of the
* filesystem. While it might seem sensible to start scanning
* backwards or even to alternate looking forward and backward,
* this approach fails badly when the filesystem is nearly full.
* Specifically, we first search all the areas that have no space
* and finally try the one preceding that. We repeat this on
* every request and in the case of the final block end up
* searching the entire filesystem. By jumping to the front
* of the filesystem, our future forward searches always look
* in new cylinder groups so finds every possible block after
* one pass over the filesystem.
*/
prefcg = ino_to_cg(fs, pip->i_number);
for (cg = prefcg; cg < fs->fs_ncg; cg++)
if (fs->fs_cs(fs, cg).cs_ndir < maxndir &&
fs->fs_cs(fs, cg).cs_nifree >= minifree &&
fs->fs_cs(fs, cg).cs_nbfree >= minbfree) {
if (fs->fs_contigdirs[cg] < maxcontigdirs)
return ((ino_t)(fs->fs_ipg * cg));
}
for (cg = 0; cg < prefcg; cg++)
if (fs->fs_cs(fs, cg).cs_ndir < maxndir &&
fs->fs_cs(fs, cg).cs_nifree >= minifree &&
fs->fs_cs(fs, cg).cs_nbfree >= minbfree) {
if (fs->fs_contigdirs[cg] < maxcontigdirs)
return ((ino_t)(fs->fs_ipg * cg));
}
/*
* This is a backstop when we have deficit in space.
*/
for (cg = prefcg; cg < fs->fs_ncg; cg++)
if (fs->fs_cs(fs, cg).cs_nifree >= avgifree)
return ((ino_t)(fs->fs_ipg * cg));
for (cg = 0; cg < prefcg; cg++)
if (fs->fs_cs(fs, cg).cs_nifree >= avgifree)
break;
return ((ino_t)(fs->fs_ipg * cg));
}
/*
* 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 and the next fs_maxbpg 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. The first indirect is allocated immediately following the last
* direct block and the data blocks for the first indirect immediately
* follow it.
*
* If no blocks have been allocated in any other section, the indirect
* block(s) are allocated in the same cylinder group as its inode in an
* area reserved immediately following the inode blocks. The policy for
* the data blocks is to place them 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 or the previous block is a hole, then the information on
* the previous allocation is unavailable; here a best guess is made based
* on the logical block number being allocated.
*
* If a section is already partially allocated, the policy is to
* allocate blocks contiguously within the section if possible.
*/
ufs2_daddr_t
ffs_blkpref_ufs1(struct inode *ip,
ufs_lbn_t lbn,
int indx,
ufs1_daddr_t *bap)
{
struct fs *fs;
u_int cg, inocg;
u_int avgbfree, startcg;
ufs2_daddr_t pref, prevbn;
KASSERT(indx <= 0 || bap != NULL, ("need non-NULL bap"));
mtx_assert(UFS_MTX(ITOUMP(ip)), MA_OWNED);
fs = ITOFS(ip);
/*
* Allocation of indirect blocks is indicated by passing negative
* values in indx: -1 for single indirect, -2 for double indirect,
* -3 for triple indirect. As noted below, we attempt to allocate
* the first indirect inline with the file data. For all later
* indirect blocks, the data is often allocated in other cylinder
* groups. However to speed random file access and to speed up
* fsck, the filesystem reserves the first fs_metaspace blocks
* (typically half of fs_minfree) of the data area of each cylinder
* group to hold these later indirect blocks.
*/
inocg = ino_to_cg(fs, ip->i_number);
if (indx < 0) {
/*
* Our preference for indirect blocks is the zone at the
* beginning of the inode's cylinder group data area that
* we try to reserve for indirect blocks.
*/
pref = cgmeta(fs, inocg);
/*
* If we are allocating the first indirect block, try to
* place it immediately following the last direct block.
*/
if (indx == -1 && lbn < UFS_NDADDR + NINDIR(fs) &&
ip->i_din1->di_db[UFS_NDADDR - 1] != 0)
pref = ip->i_din1->di_db[UFS_NDADDR - 1] + fs->fs_frag;
return (pref);
}
/*
* If we are allocating the first data block in the first indirect
* block and the indirect has been allocated in the data block area,
* try to place it immediately following the indirect block.
*/
if (lbn == UFS_NDADDR) {
pref = ip->i_din1->di_ib[0];
if (pref != 0 && pref >= cgdata(fs, inocg) &&
pref < cgbase(fs, inocg + 1))
return (pref + fs->fs_frag);
}
/*
* If we are at the beginning of a file, or we have already allocated
* the maximum number of blocks per cylinder group, or we do not
* have a block allocated immediately preceding us, then we need
* to decide where to start allocating new blocks.
*/
if (indx == 0) {
prevbn = 0;
} else {
prevbn = bap[indx - 1];
if (UFS_CHECK_BLKNO(ITOVFS(ip), ip->i_number, prevbn,
fs->fs_bsize) != 0)
prevbn = 0;
}
if (indx % fs->fs_maxbpg == 0 || prevbn == 0) {
/*
* If we are allocating a directory data block, we want
* to place it in the metadata area.
*/
if ((ip->i_mode & IFMT) == IFDIR)
return (cgmeta(fs, inocg));
/*
* Until we fill all the direct and all the first indirect's
* blocks, we try to allocate in the data area of the inode's
* cylinder group.
*/
if (lbn < UFS_NDADDR + NINDIR(fs))
return (cgdata(fs, inocg));
/*
* Find a cylinder with greater than average number of
* unused data blocks.
*/
if (indx == 0 || prevbn == 0)
startcg = inocg + lbn / fs->fs_maxbpg;
else
startcg = dtog(fs, prevbn) + 1;
startcg %= fs->fs_ncg;
avgbfree = fs->fs_cstotal.cs_nbfree / fs->fs_ncg;
for (cg = startcg; cg < fs->fs_ncg; cg++)
if (fs->fs_cs(fs, cg).cs_nbfree >= avgbfree) {
fs->fs_cgrotor = cg;
return (cgdata(fs, cg));
}
for (cg = 0; cg <= startcg; cg++)
if (fs->fs_cs(fs, cg).cs_nbfree >= avgbfree) {
fs->fs_cgrotor = cg;
return (cgdata(fs, cg));
}
return (0);
}
/*
* Otherwise, we just always try to lay things out contiguously.
*/
return (prevbn + fs->fs_frag);
}
/*
* Same as above, but for UFS2
*/
ufs2_daddr_t
ffs_blkpref_ufs2(struct inode *ip,
ufs_lbn_t lbn,
int indx,
ufs2_daddr_t *bap)
{
struct fs *fs;
u_int cg, inocg;
u_int avgbfree, startcg;
ufs2_daddr_t pref, prevbn;
KASSERT(indx <= 0 || bap != NULL, ("need non-NULL bap"));
mtx_assert(UFS_MTX(ITOUMP(ip)), MA_OWNED);
fs = ITOFS(ip);
/*
* Allocation of indirect blocks is indicated by passing negative
* values in indx: -1 for single indirect, -2 for double indirect,
* -3 for triple indirect. As noted below, we attempt to allocate
* the first indirect inline with the file data. For all later
* indirect blocks, the data is often allocated in other cylinder
* groups. However to speed random file access and to speed up
* fsck, the filesystem reserves the first fs_metaspace blocks
* (typically half of fs_minfree) of the data area of each cylinder
* group to hold these later indirect blocks.
*/
inocg = ino_to_cg(fs, ip->i_number);
if (indx < 0) {
/*
* Our preference for indirect blocks is the zone at the
* beginning of the inode's cylinder group data area that
* we try to reserve for indirect blocks.
*/
pref = cgmeta(fs, inocg);
/*
* If we are allocating the first indirect block, try to
* place it immediately following the last direct block.
*/
if (indx == -1 && lbn < UFS_NDADDR + NINDIR(fs) &&
ip->i_din2->di_db[UFS_NDADDR - 1] != 0)
pref = ip->i_din2->di_db[UFS_NDADDR - 1] + fs->fs_frag;
return (pref);
}
/*
* If we are allocating the first data block in the first indirect
* block and the indirect has been allocated in the data block area,
* try to place it immediately following the indirect block.
*/
if (lbn == UFS_NDADDR) {
pref = ip->i_din2->di_ib[0];
if (pref != 0 && pref >= cgdata(fs, inocg) &&
pref < cgbase(fs, inocg + 1))
return (pref + fs->fs_frag);
}
/*
* If we are at the beginning of a file, or we have already allocated
* the maximum number of blocks per cylinder group, or we do not
* have a block allocated immediately preceding us, then we need
* to decide where to start allocating new blocks.
*/
if (indx == 0) {
prevbn = 0;
} else {
prevbn = bap[indx - 1];
if (UFS_CHECK_BLKNO(ITOVFS(ip), ip->i_number, prevbn,
fs->fs_bsize) != 0)
prevbn = 0;
}
if (indx % fs->fs_maxbpg == 0 || prevbn == 0) {
/*
* If we are allocating a directory data block, we want
* to place it in the metadata area.
*/
if ((ip->i_mode & IFMT) == IFDIR)
return (cgmeta(fs, inocg));
/*
* Until we fill all the direct and all the first indirect's
* blocks, we try to allocate in the data area of the inode's
* cylinder group.
*/
if (lbn < UFS_NDADDR + NINDIR(fs))
return (cgdata(fs, inocg));
/*
* Find a cylinder with greater than average number of
* unused data blocks.
*/
if (indx == 0 || prevbn == 0)
startcg = inocg + lbn / fs->fs_maxbpg;
else
startcg = dtog(fs, prevbn) + 1;
startcg %= fs->fs_ncg;
avgbfree = fs->fs_cstotal.cs_nbfree / fs->fs_ncg;
for (cg = startcg; cg < fs->fs_ncg; cg++)
if (fs->fs_cs(fs, cg).cs_nbfree >= avgbfree) {
fs->fs_cgrotor = cg;
return (cgdata(fs, cg));
}
for (cg = 0; cg <= startcg; cg++)
if (fs->fs_cs(fs, cg).cs_nbfree >= avgbfree) {
fs->fs_cgrotor = cg;
return (cgdata(fs, cg));
}
return (0);
}
/*
* Otherwise, we just always try to lay things out contiguously.
*/
return (prevbn + fs->fs_frag);
}
/*
* Implement the cylinder overflow algorithm.
*
* The policy implemented by this algorithm is:
* 1) allocate the block in its requested cylinder group.
* 2) quadratically rehash on the cylinder group number.
* 3) brute force search for a free block.
*
* Must be called with the UFS lock held. Will release the lock on success
* and return with it held on failure.
*/
/*VARARGS5*/
static ufs2_daddr_t
ffs_hashalloc(struct inode *ip,
u_int cg,
ufs2_daddr_t pref,
int size, /* Search size for data blocks, mode for inodes */
int rsize, /* Real allocated size. */
allocfcn_t *allocator)
{
struct fs *fs;
ufs2_daddr_t result;
u_int i, icg = cg;
mtx_assert(UFS_MTX(ITOUMP(ip)), MA_OWNED);
#ifdef INVARIANTS
if (ITOV(ip)->v_mount->mnt_kern_flag & MNTK_SUSPENDED)
panic("ffs_hashalloc: allocation on suspended filesystem");
#endif
fs = ITOFS(ip);
/*
* 1: preferred cylinder group
*/
result = (*allocator)(ip, cg, pref, size, rsize);
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)(ip, cg, 0, size, rsize);
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)(ip, cg, 0, size, rsize);
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 ufs2_daddr_t
ffs_fragextend(struct inode *ip,
u_int cg,
ufs2_daddr_t bprev,
int osize,
int nsize)
{
struct fs *fs;
struct cg *cgp;
struct buf *bp;
struct ufsmount *ump;
int nffree;
long bno;
int frags, bbase;
int i, error;
u_int8_t *blksfree;
ump = ITOUMP(ip);
fs = ump->um_fs;
if (fs->fs_cs(fs, 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);
}
UFS_UNLOCK(ump);
if ((error = ffs_getcg(fs, ump->um_devvp, cg, 0, &bp, &cgp)) != 0)
goto fail;
bno = dtogd(fs, bprev);
blksfree = cg_blksfree(cgp);
for (i = numfrags(fs, osize); i < frags; i++)
if (isclr(blksfree, bno + i))
goto fail;
/*
* 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(blksfree, bno + i))
break;
cgp->cg_frsum[i - numfrags(fs, osize)]--;
if (i != frags)
cgp->cg_frsum[i - frags]++;
for (i = numfrags(fs, osize), nffree = 0; i < frags; i++) {
clrbit(blksfree, bno + i);
cgp->cg_cs.cs_nffree--;
nffree++;
}
UFS_LOCK(ump);
fs->fs_cstotal.cs_nffree -= nffree;
fs->fs_cs(fs, cg).cs_nffree -= nffree;
fs->fs_fmod = 1;
ACTIVECLEAR(fs, cg);
UFS_UNLOCK(ump);
if (DOINGSOFTDEP(ITOV(ip)))
softdep_setup_blkmapdep(bp, UFSTOVFS(ump), bprev,
frags, numfrags(fs, osize));
bdwrite(bp);
return (bprev);
fail:
brelse(bp);
UFS_LOCK(ump);
return (0);
}
/*
* 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 ufs2_daddr_t
ffs_alloccg(struct inode *ip,
u_int cg,
ufs2_daddr_t bpref,
int size,
int rsize)
{
struct fs *fs;
struct cg *cgp;
struct buf *bp;
struct ufsmount *ump;
ufs1_daddr_t bno;
ufs2_daddr_t blkno;
int i, allocsiz, error, frags;
u_int8_t *blksfree;
ump = ITOUMP(ip);
fs = ump->um_fs;
if (fs->fs_cs(fs, cg).cs_nbfree == 0 && size == fs->fs_bsize)
return (0);
UFS_UNLOCK(ump);
if ((error = ffs_getcg(fs, ump->um_devvp, cg, 0, &bp, &cgp)) != 0 ||
(cgp->cg_cs.cs_nbfree == 0 && size == fs->fs_bsize))
goto fail;
if (size == fs->fs_bsize) {
UFS_LOCK(ump);
blkno = ffs_alloccgblk(ip, bp, bpref, rsize);
ACTIVECLEAR(fs, cg);
UFS_UNLOCK(ump);
bdwrite(bp);
return (blkno);
}
/*
* 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
*/
blksfree = cg_blksfree(cgp);
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)
goto fail;
UFS_LOCK(ump);
blkno = ffs_alloccgblk(ip, bp, bpref, rsize);
ACTIVECLEAR(fs, cg);
UFS_UNLOCK(ump);
bdwrite(bp);
return (blkno);
}
KASSERT(size == rsize,
("ffs_alloccg: size(%d) != rsize(%d)", size, rsize));
bno = ffs_mapsearch(fs, cgp, bpref, allocsiz);
if (bno < 0)
goto fail;
for (i = 0; i < frags; i++)
clrbit(blksfree, bno + i);
cgp->cg_cs.cs_nffree -= frags;
cgp->cg_frsum[allocsiz]--;
if (frags != allocsiz)
cgp->cg_frsum[allocsiz - frags]++;
UFS_LOCK(ump);
fs->fs_cstotal.cs_nffree -= frags;
fs->fs_cs(fs, cg).cs_nffree -= frags;
fs->fs_fmod = 1;
blkno = cgbase(fs, cg) + bno;
ACTIVECLEAR(fs, cg);
UFS_UNLOCK(ump);
if (DOINGSOFTDEP(ITOV(ip)))
softdep_setup_blkmapdep(bp, UFSTOVFS(ump), blkno, frags, 0);
bdwrite(bp);
return (blkno);
fail:
brelse(bp);
UFS_LOCK(ump);
return (0);
}
/*
* 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 ufs2_daddr_t
ffs_alloccgblk(struct inode *ip,
struct buf *bp,
ufs2_daddr_t bpref,
int size)
{
struct fs *fs;
struct cg *cgp;
struct ufsmount *ump;
ufs1_daddr_t bno;
ufs2_daddr_t blkno;
u_int8_t *blksfree;
int i, cgbpref;
ump = ITOUMP(ip);
fs = ump->um_fs;
mtx_assert(UFS_MTX(ump), MA_OWNED);
cgp = (struct cg *)bp->b_data;
blksfree = cg_blksfree(cgp);
if (bpref == 0) {
bpref = cgbase(fs, cgp->cg_cgx) + cgp->cg_rotor + fs->fs_frag;
} else if ((cgbpref = dtog(fs, bpref)) != cgp->cg_cgx) {
/* map bpref to correct zone in this cg */
if (bpref < cgdata(fs, cgbpref))
bpref = cgmeta(fs, cgp->cg_cgx);
else
bpref = cgdata(fs, cgp->cg_cgx);
}
/*
* if the requested block is available, use it
*/
bno = dtogd(fs, blknum(fs, bpref));
if (ffs_isblock(fs, blksfree, fragstoblks(fs, bno)))
goto gotit;
/*
* Take the next available block in this cylinder group.
*/
bno = ffs_mapsearch(fs, cgp, bpref, (int)fs->fs_frag);
if (bno < 0)
return (0);
/* Update cg_rotor only if allocated from the data zone */
if (bno >= dtogd(fs, cgdata(fs, cgp->cg_cgx)))
cgp->cg_rotor = bno;
gotit:
blkno = fragstoblks(fs, bno);
ffs_clrblock(fs, blksfree, (long)blkno);
ffs_clusteracct(fs, cgp, blkno, -1);
cgp->cg_cs.cs_nbfree--;
fs->fs_cstotal.cs_nbfree--;
fs->fs_cs(fs, cgp->cg_cgx).cs_nbfree--;
fs->fs_fmod = 1;
blkno = cgbase(fs, cgp->cg_cgx) + bno;
/*
* If the caller didn't want the whole block free the frags here.
*/
size = numfrags(fs, size);
if (size != fs->fs_frag) {
bno = dtogd(fs, blkno);
for (i = size; i < fs->fs_frag; i++)
setbit(blksfree, bno + i);
i = fs->fs_frag - size;
cgp->cg_cs.cs_nffree += i;
fs->fs_cstotal.cs_nffree += i;
fs->fs_cs(fs, cgp->cg_cgx).cs_nffree += i;
fs->fs_fmod = 1;
cgp->cg_frsum[i]++;
}
/* XXX Fixme. */
UFS_UNLOCK(ump);
if (DOINGSOFTDEP(ITOV(ip)))
softdep_setup_blkmapdep(bp, UFSTOVFS(ump), blkno, size, 0);
UFS_LOCK(ump);
return (blkno);
}
/*
* 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 ufs2_daddr_t
ffs_clusteralloc(struct inode *ip,
u_int cg,
ufs2_daddr_t bpref,
int len)
{
struct fs *fs;
struct cg *cgp;
struct buf *bp;
struct ufsmount *ump;
int i, run, bit, map, got, error;
ufs2_daddr_t bno;
u_char *mapp;
int32_t *lp;
u_int8_t *blksfree;
ump = ITOUMP(ip);
fs = ump->um_fs;
if (fs->fs_maxcluster[cg] < len)
return (0);
UFS_UNLOCK(ump);
if ((error = ffs_getcg(fs, ump->um_devvp, cg, 0, &bp, &cgp)) != 0) {
UFS_LOCK(ump);
return (0);
}
/*
* Check to see if a cluster of the needed size (or bigger) is
* available in this cylinder group.
*/
lp = &cg_clustersum(cgp)[len];
for (i = len; i <= fs->fs_contigsumsize; i++)
if (*lp++ > 0)
break;
if (i > fs->fs_contigsumsize) {
/*
* This is the first time looking for a cluster in this
* cylinder group. Update the cluster summary information
* to reflect the true maximum sized cluster so that
* future cluster allocation requests can avoid reading
* the cylinder group map only to find no clusters.
*/
lp = &cg_clustersum(cgp)[len - 1];
for (i = len - 1; i > 0; i--)
if (*lp-- > 0)
break;
UFS_LOCK(ump);
fs->fs_maxcluster[cg] = i;
brelse(bp);
return (0);
}
/*
* 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 = cgdata(fs, cg);
else
bpref = blknum(fs, bpref);
bpref = fragstoblks(fs, dtogd(fs, bpref));
mapp = &cg_clustersfree(cgp)[bpref / NBBY];
map = *mapp++;
bit = 1 << (bpref % NBBY);
for (run = 0, got = bpref; got < cgp->cg_nclusterblks; got++) {
if ((map & bit) == 0) {
run = 0;
} else {
run++;
if (run == len)
break;
}
if ((got & (NBBY - 1)) != (NBBY - 1)) {
bit <<= 1;
} else {
map = *mapp++;
bit = 1;
}
}
if (got >= cgp->cg_nclusterblks) {
UFS_LOCK(ump);
brelse(bp);
return (0);
}
/*
* Allocate the cluster that we have found.
*/
blksfree = cg_blksfree(cgp);
for (i = 1; i <= len; i++)
if (!ffs_isblock(fs, blksfree, got - run + i))
panic("ffs_clusteralloc: map mismatch");
bno = cgbase(fs, cg) + blkstofrags(fs, got - run + 1);
if (dtog(fs, bno) != cg)
panic("ffs_clusteralloc: allocated out of group");
len = blkstofrags(fs, len);
UFS_LOCK(ump);
for (i = 0; i < len; i += fs->fs_frag)
if (ffs_alloccgblk(ip, bp, bno + i, fs->fs_bsize) != bno + i)
panic("ffs_clusteralloc: lost block");
ACTIVECLEAR(fs, cg);
UFS_UNLOCK(ump);
bdwrite(bp);
return (bno);
}
static inline struct buf *
getinobuf(struct inode *ip,
u_int cg,
u_int32_t cginoblk,
int gbflags)
{
struct fs *fs;
fs = ITOFS(ip);
return (getblk(ITODEVVP(ip), fsbtodb(fs, ino_to_fsba(fs,
cg * fs->fs_ipg + cginoblk)), (int)fs->fs_bsize, 0, 0,
gbflags));
}
/*
* Synchronous inode initialization is needed only when barrier writes do not
* work as advertised, and will impose a heavy cost on file creation in a newly
* created filesystem.
*/
static int doasyncinodeinit = 1;
SYSCTL_INT(_vfs_ffs, OID_AUTO, doasyncinodeinit, CTLFLAG_RWTUN,
&doasyncinodeinit, 0,
"Perform inode block initialization using asynchronous writes");
/*
* 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 ufs2_daddr_t
ffs_nodealloccg(struct inode *ip,
u_int cg,
ufs2_daddr_t ipref,
int mode,
int unused)
{
struct fs *fs;
struct cg *cgp;
struct buf *bp, *ibp;
struct ufsmount *ump;
u_int8_t *inosused, *loc;
struct ufs2_dinode *dp2;
int error, start, len, i;
u_int32_t old_initediblk;
ump = ITOUMP(ip);
fs = ump->um_fs;
check_nifree:
if (fs->fs_cs(fs, cg).cs_nifree == 0)
return (0);
UFS_UNLOCK(ump);
if ((error = ffs_getcg(fs, ump->um_devvp, cg, 0, &bp, &cgp)) != 0) {
UFS_LOCK(ump);
return (0);
}
restart:
if (cgp->cg_cs.cs_nifree == 0) {
brelse(bp);
UFS_LOCK(ump);
return (0);
}
inosused = cg_inosused(cgp);
if (ipref) {
ipref %= fs->fs_ipg;
if (isclr(inosused, ipref))
goto gotit;
}
start = cgp->cg_irotor / NBBY;
len = howmany(fs->fs_ipg - cgp->cg_irotor, NBBY);
loc = memcchr(&inosused[start], 0xff, len);
if (loc == NULL) {
len = start + 1;
start = 0;
loc = memcchr(&inosused[start], 0xff, len);
if (loc == NULL) {
printf("cg = %d, irotor = %ld, fs = %s\n",
cg, (long)cgp->cg_irotor, fs->fs_fsmnt);
panic("ffs_nodealloccg: map corrupted");
/* NOTREACHED */
}
}
ipref = (loc - inosused) * NBBY + ffs(~*loc) - 1;
gotit:
/*
* Check to see if we need to initialize more inodes.
*/
if (fs->fs_magic == FS_UFS2_MAGIC &&
ipref + INOPB(fs) > cgp->cg_initediblk &&
cgp->cg_initediblk < cgp->cg_niblk) {
old_initediblk = cgp->cg_initediblk;
/*
* Free the cylinder group lock before writing the
* initialized inode block. Entering the
* babarrierwrite() with the cylinder group lock
* causes lock order violation between the lock and
* snaplk.
*
* Another thread can decide to initialize the same
* inode block, but whichever thread first gets the
* cylinder group lock after writing the newly
* allocated inode block will update it and the other
* will realize that it has lost and leave the
* cylinder group unchanged.
*/
ibp = getinobuf(ip, cg, old_initediblk, GB_LOCK_NOWAIT);
brelse(bp);
if (ibp == NULL) {
/*
* The inode block buffer is already owned by
* another thread, which must initialize it.
* Wait on the buffer to allow another thread
* to finish the updates, with dropped cg
* buffer lock, then retry.
*/
ibp = getinobuf(ip, cg, old_initediblk, 0);
brelse(ibp);
UFS_LOCK(ump);
goto check_nifree;
}
bzero(ibp->b_data, (int)fs->fs_bsize);
dp2 = (struct ufs2_dinode *)(ibp->b_data);
for (i = 0; i < INOPB(fs); i++) {
while (dp2->di_gen == 0)
dp2->di_gen = arc4random();
dp2++;
}
/*
* Rather than adding a soft updates dependency to ensure
* that the new inode block is written before it is claimed
* by the cylinder group map, we just do a barrier write
* here. The barrier write will ensure that the inode block
* gets written before the updated cylinder group map can be
* written. The barrier write should only slow down bulk
* loading of newly created filesystems.
*/
if (doasyncinodeinit)
babarrierwrite(ibp);
else
bwrite(ibp);
/*
* After the inode block is written, try to update the
* cg initediblk pointer. If another thread beat us
* to it, then leave it unchanged as the other thread
* has already set it correctly.
*/
error = ffs_getcg(fs, ump->um_devvp, cg, 0, &bp, &cgp);
UFS_LOCK(ump);
ACTIVECLEAR(fs, cg);
UFS_UNLOCK(ump);
if (error != 0)
return (error);
if (cgp->cg_initediblk == old_initediblk)
cgp->cg_initediblk += INOPB(fs);
goto restart;
}
cgp->cg_irotor = ipref;
UFS_LOCK(ump);
ACTIVECLEAR(fs, cg);
setbit(inosused, ipref);
cgp->cg_cs.cs_nifree--;
fs->fs_cstotal.cs_nifree--;
fs->fs_cs(fs, cg).cs_nifree--;
fs->fs_fmod = 1;
if ((mode & IFMT) == IFDIR) {
cgp->cg_cs.cs_ndir++;
fs->fs_cstotal.cs_ndir++;
fs->fs_cs(fs, cg).cs_ndir++;
}
UFS_UNLOCK(ump);
if (DOINGSOFTDEP(ITOV(ip)))
softdep_setup_inomapdep(bp, ip, cg * fs->fs_ipg + ipref, mode);
bdwrite(bp);
return ((ino_t)(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.
*/
static void
ffs_blkfree_cg(struct ufsmount *ump,
struct fs *fs,
struct vnode *devvp,
ufs2_daddr_t bno,
long size,
ino_t inum,
struct workhead *dephd)
{
struct mount *mp;
struct cg *cgp;
struct buf *bp;
daddr_t dbn;
ufs1_daddr_t fragno, cgbno;
int i, blk, frags, bbase, error;
u_int cg;
u_int8_t *blksfree;
struct cdev *dev;
cg = dtog(fs, bno);
if (devvp->v_type == VREG) {
/* devvp is a snapshot */
MPASS(devvp->v_mount->mnt_data == ump);
dev = ump->um_devvp->v_rdev;
} else if (devvp->v_type == VCHR) {
/*
* devvp is a normal disk device
* XXXKIB: devvp is not locked there, v_rdev access depends on
* busy mount, which prevents mntfs devvp from reclamation.
*/
dev = devvp->v_rdev;
} else
return;
#ifdef INVARIANTS
if ((u_int)size > fs->fs_bsize || fragoff(fs, size) != 0 ||
fragnum(fs, bno) + numfrags(fs, size) > fs->fs_frag) {
printf("dev=%s, bno = %jd, bsize = %ld, size = %ld, fs = %s\n",
devtoname(dev), (intmax_t)bno, (long)fs->fs_bsize,
size, fs->fs_fsmnt);
panic("ffs_blkfree_cg: bad size");
}
#endif
if ((u_int)bno >= fs->fs_size) {
printf("bad block %jd, ino %lu\n", (intmax_t)bno,
(u_long)inum);
ffs_fserr(fs, inum, "bad block");
return;
}
if ((error = ffs_getcg(fs, devvp, cg, GB_CVTENXIO, &bp, &cgp)) != 0) {
if (!ffs_fsfail_cleanup(ump, error) ||
!MOUNTEDSOFTDEP(UFSTOVFS(ump)) || devvp->v_type != VCHR)
return;
if (devvp->v_type == VREG)
dbn = fragstoblks(fs, cgtod(fs, cg));
else
dbn = fsbtodb(fs, cgtod(fs, cg));
error = getblkx(devvp, dbn, dbn, fs->fs_cgsize, 0, 0, 0, &bp);
KASSERT(error == 0, ("getblkx failed"));
softdep_setup_blkfree(UFSTOVFS(ump), bp, bno,
numfrags(fs, size), dephd);
bp->b_flags |= B_RELBUF | B_NOCACHE;
bp->b_flags &= ~B_CACHE;
bawrite(bp);
return;
}
cgbno = dtogd(fs, bno);
blksfree = cg_blksfree(cgp);
UFS_LOCK(ump);
if (size == fs->fs_bsize) {
fragno = fragstoblks(fs, cgbno);
if (!ffs_isfreeblock(fs, blksfree, fragno)) {
if (devvp->v_type == VREG) {
UFS_UNLOCK(ump);
/* devvp is a snapshot */
brelse(bp);
return;
}
printf("dev = %s, block = %jd, fs = %s\n",
devtoname(dev), (intmax_t)bno, fs->fs_fsmnt);
panic("ffs_blkfree_cg: freeing free block");
}
ffs_setblock(fs, blksfree, fragno);
ffs_clusteracct(fs, cgp, fragno, 1);
cgp->cg_cs.cs_nbfree++;
fs->fs_cstotal.cs_nbfree++;
fs->fs_cs(fs, cg).cs_nbfree++;
} else {
bbase = cgbno - fragnum(fs, cgbno);
/*
* decrement the counts associated with the old frags
*/
blk = blkmap(fs, blksfree, bbase);
ffs_fragacct(fs, blk, cgp->cg_frsum, -1);
/*
* deallocate the fragment
*/
frags = numfrags(fs, size);
for (i = 0; i < frags; i++) {
if (isset(blksfree, cgbno + i)) {
printf("dev = %s, block = %jd, fs = %s\n",
devtoname(dev), (intmax_t)(bno + i),
fs->fs_fsmnt);
panic("ffs_blkfree_cg: freeing free frag");
}
setbit(blksfree, cgbno + i);
}
cgp->cg_cs.cs_nffree += i;
fs->fs_cstotal.cs_nffree += i;
fs->fs_cs(fs, cg).cs_nffree += i;
/*
* add back in counts associated with the new frags
*/
blk = blkmap(fs, blksfree, bbase);
ffs_fragacct(fs, blk, cgp->cg_frsum, 1);
/*
* if a complete block has been reassembled, account for it
*/
fragno = fragstoblks(fs, bbase);
if (ffs_isblock(fs, blksfree, fragno)) {
cgp->cg_cs.cs_nffree -= fs->fs_frag;
fs->fs_cstotal.cs_nffree -= fs->fs_frag;
fs->fs_cs(fs, cg).cs_nffree -= fs->fs_frag;
ffs_clusteracct(fs, cgp, fragno, 1);
cgp->cg_cs.cs_nbfree++;
fs->fs_cstotal.cs_nbfree++;
fs->fs_cs(fs, cg).cs_nbfree++;
}
}
fs->fs_fmod = 1;
ACTIVECLEAR(fs, cg);
UFS_UNLOCK(ump);
mp = UFSTOVFS(ump);
if (MOUNTEDSOFTDEP(mp) && devvp->v_type == VCHR)
softdep_setup_blkfree(UFSTOVFS(ump), bp, bno,
numfrags(fs, size), dephd);
bdwrite(bp);
}
/*
* Structures and routines associated with trim management.
*
* The following requests are passed to trim_lookup to indicate
* the actions that should be taken.
*/
#define NEW 1 /* if found, error else allocate and hash it */
#define OLD 2 /* if not found, error, else return it */
#define REPLACE 3 /* if not found, error else unhash and reallocate it */
#define DONE 4 /* if not found, error else unhash and return it */
#define SINGLE 5 /* don't look up, just allocate it and don't hash it */
MALLOC_DEFINE(M_TRIM, "ufs_trim", "UFS trim structures");
#define TRIMLIST_HASH(ump, key) \
(&(ump)->um_trimhash[(key) & (ump)->um_trimlisthashsize])
/*
* These structures describe each of the block free requests aggregated
* together to make up a trim request.
*/
struct trim_blkreq {
TAILQ_ENTRY(trim_blkreq) blkreqlist;
ufs2_daddr_t bno;
long size;
struct workhead *pdephd;
struct workhead dephd;
};
/*
* Description of a trim request.
*/
struct ffs_blkfree_trim_params {
TAILQ_HEAD(, trim_blkreq) blklist;
LIST_ENTRY(ffs_blkfree_trim_params) hashlist;
struct task task;
struct ufsmount *ump;
struct vnode *devvp;
ino_t inum;
ufs2_daddr_t bno;
long size;
long key;
};
static void ffs_blkfree_trim_completed(struct buf *);
static void ffs_blkfree_trim_task(void *ctx, int pending __unused);
static struct ffs_blkfree_trim_params *trim_lookup(struct ufsmount *,
struct vnode *, ufs2_daddr_t, long, ino_t, u_long, int);
static void ffs_blkfree_sendtrim(struct ffs_blkfree_trim_params *);
/*
* Called on trim completion to start a task to free the associated block(s).
*/
static void
ffs_blkfree_trim_completed(struct buf *bp)
{
struct ffs_blkfree_trim_params *tp;
tp = bp->b_fsprivate1;
free(bp, M_TRIM);
TASK_INIT(&tp->task, 0, ffs_blkfree_trim_task, tp);
taskqueue_enqueue(tp->ump->um_trim_tq, &tp->task);
}
/*
* Trim completion task that free associated block(s).
*/
static void
ffs_blkfree_trim_task(void *ctx, int pending)
{
struct ffs_blkfree_trim_params *tp;
struct trim_blkreq *blkelm;
struct ufsmount *ump;
tp = ctx;
ump = tp->ump;
while ((blkelm = TAILQ_FIRST(&tp->blklist)) != NULL) {
ffs_blkfree_cg(ump, ump->um_fs, tp->devvp, blkelm->bno,
blkelm->size, tp->inum, blkelm->pdephd);
TAILQ_REMOVE(&tp->blklist, blkelm, blkreqlist);
free(blkelm, M_TRIM);
}
vn_finished_secondary_write(UFSTOVFS(ump));
UFS_LOCK(ump);
ump->um_trim_inflight -= 1;
ump->um_trim_inflight_blks -= numfrags(ump->um_fs, tp->size);
UFS_UNLOCK(ump);
free(tp, M_TRIM);
}
/*
* Lookup a trim request by inode number.
* Allocate if requested (NEW, REPLACE, SINGLE).
*/
static struct ffs_blkfree_trim_params *
trim_lookup(struct ufsmount *ump,
struct vnode *devvp,
ufs2_daddr_t bno,
long size,
ino_t inum,
u_long key,
int alloctype)
{
struct trimlist_hashhead *tphashhead;
struct ffs_blkfree_trim_params *tp, *ntp;
ntp = malloc(sizeof(struct ffs_blkfree_trim_params), M_TRIM, M_WAITOK);
if (alloctype != SINGLE) {
KASSERT(key >= FIRST_VALID_KEY, ("trim_lookup: invalid key"));
UFS_LOCK(ump);
tphashhead = TRIMLIST_HASH(ump, key);
LIST_FOREACH(tp, tphashhead, hashlist)
if (key == tp->key)
break;
}
switch (alloctype) {
case NEW:
KASSERT(tp == NULL, ("trim_lookup: found trim"));
break;
case OLD:
KASSERT(tp != NULL,
("trim_lookup: missing call to ffs_blkrelease_start()"));
UFS_UNLOCK(ump);
free(ntp, M_TRIM);
return (tp);
case REPLACE:
KASSERT(tp != NULL, ("trim_lookup: missing REPLACE trim"));
LIST_REMOVE(tp, hashlist);
/* tp will be freed by caller */
break;
case DONE:
KASSERT(tp != NULL, ("trim_lookup: missing DONE trim"));
LIST_REMOVE(tp, hashlist);
UFS_UNLOCK(ump);
free(ntp, M_TRIM);
return (tp);
}
TAILQ_INIT(&ntp->blklist);
ntp->ump = ump;
ntp->devvp = devvp;
ntp->bno = bno;
ntp->size = size;
ntp->inum = inum;
ntp->key = key;
if (alloctype != SINGLE) {
LIST_INSERT_HEAD(tphashhead, ntp, hashlist);
UFS_UNLOCK(ump);
}
return (ntp);
}
/*
* Dispatch a trim request.
*/
static void
ffs_blkfree_sendtrim(struct ffs_blkfree_trim_params *tp)
{
struct ufsmount *ump;
struct mount *mp;
struct buf *bp;
/*
* Postpone the set of the free bit in the cg bitmap until the
* BIO_DELETE is completed. Otherwise, due to disk queue
* reordering, TRIM might be issued after we reuse the block
* and write some new data into it.
*/
ump = tp->ump;
bp = malloc(sizeof(*bp), M_TRIM, M_WAITOK | M_ZERO);
bp->b_iocmd = BIO_DELETE;
bp->b_iooffset = dbtob(fsbtodb(ump->um_fs, tp->bno));
bp->b_iodone = ffs_blkfree_trim_completed;
bp->b_bcount = tp->size;
bp->b_fsprivate1 = tp;
UFS_LOCK(ump);
ump->um_trim_total += 1;
ump->um_trim_inflight += 1;
ump->um_trim_inflight_blks += numfrags(ump->um_fs, tp->size);
ump->um_trim_total_blks += numfrags(ump->um_fs, tp->size);
UFS_UNLOCK(ump);
mp = UFSTOVFS(ump);
vn_start_secondary_write(NULL, &mp, 0);
g_vfs_strategy(ump->um_bo, bp);
}
/*
* Allocate a new key to use to identify a range of blocks.
*/
u_long
ffs_blkrelease_start(struct ufsmount *ump,
struct vnode *devvp,
ino_t inum)
{
static u_long masterkey;
u_long key;
if (((ump->um_flags & UM_CANDELETE) == 0) || dotrimcons == 0)
return (SINGLETON_KEY);
do {
key = atomic_fetchadd_long(&masterkey, 1);
} while (key < FIRST_VALID_KEY);
(void) trim_lookup(ump, devvp, 0, 0, inum, key, NEW);
return (key);
}
/*
* Deallocate a key that has been used to identify a range of blocks.
*/
void
ffs_blkrelease_finish(struct ufsmount *ump, u_long key)
{
struct ffs_blkfree_trim_params *tp;
if (((ump->um_flags & UM_CANDELETE) == 0) || dotrimcons == 0)
return;
/*
* If the vfs.ffs.dotrimcons sysctl option is enabled while
* a file deletion is active, specifically after a call
* to ffs_blkrelease_start() but before the call to
* ffs_blkrelease_finish(), ffs_blkrelease_start() will
* have handed out SINGLETON_KEY rather than starting a
* collection sequence. Thus if we get a SINGLETON_KEY
* passed to ffs_blkrelease_finish(), we just return rather
* than trying to finish the nonexistent sequence.
*/
if (key == SINGLETON_KEY) {
#ifdef INVARIANTS
printf("%s: vfs.ffs.dotrimcons enabled on active filesystem\n",
ump->um_mountp->mnt_stat.f_mntonname);
#endif
return;
}
/*
* We are done with sending blocks using this key. Look up the key
* using the DONE alloctype (in tp) to request that it be unhashed
* as we will not be adding to it. If the key has never been used,
* tp->size will be zero, so we can just free tp. Otherwise the call
* to ffs_blkfree_sendtrim(tp) causes the block range described by
* tp to be issued (and then tp to be freed).
*/
tp = trim_lookup(ump, NULL, 0, 0, 0, key, DONE);
if (tp->size == 0)
free(tp, M_TRIM);
else
ffs_blkfree_sendtrim(tp);
}
/*
* Setup to free a block or fragment.
*
* Check for snapshots that might want to claim the block.
* If trims are requested, prepare a trim request. Attempt to
* aggregate consecutive blocks into a single trim request.
*/
void
ffs_blkfree(struct ufsmount *ump,
struct fs *fs,
struct vnode *devvp,
ufs2_daddr_t bno,
long size,
ino_t inum,
enum vtype vtype,
struct workhead *dephd,
u_long key)
{
struct ffs_blkfree_trim_params *tp, *ntp;
struct trim_blkreq *blkelm;
/*
* Check to see if a snapshot wants to claim the block.
* Check that devvp is a normal disk device, not a snapshot,
* it has a snapshot(s) associated with it, and one of the
* snapshots wants to claim the block.
*/
if (devvp->v_type == VCHR &&
(devvp->v_vflag & VV_COPYONWRITE) &&
ffs_snapblkfree(fs, devvp, bno, size, inum, vtype, dephd)) {
return;
}
/*
* Nothing to delay if TRIM is not required for this block or TRIM
* is disabled or the operation is performed on a snapshot.
*/
if (key == NOTRIM_KEY || ((ump->um_flags & UM_CANDELETE) == 0) ||
devvp->v_type == VREG) {
ffs_blkfree_cg(ump, fs, devvp, bno, size, inum, dephd);
return;
}
blkelm = malloc(sizeof(struct trim_blkreq), M_TRIM, M_WAITOK);
blkelm->bno = bno;
blkelm->size = size;
if (dephd == NULL) {
blkelm->pdephd = NULL;
} else {
LIST_INIT(&blkelm->dephd);
LIST_SWAP(dephd, &blkelm->dephd, worklist, wk_list);
blkelm->pdephd = &blkelm->dephd;
}
if (key == SINGLETON_KEY) {
/*
* Just a single non-contiguous piece. Use the SINGLE
* alloctype to return a trim request that will not be
* hashed for future lookup.
*/
tp = trim_lookup(ump, devvp, bno, size, inum, key, SINGLE);
TAILQ_INSERT_HEAD(&tp->blklist, blkelm, blkreqlist);
ffs_blkfree_sendtrim(tp);
return;
}
/*
* The callers of this function are not tracking whether or not
* the blocks are contiguous. They are just saying that they
* are freeing a set of blocks. It is this code that determines
* the pieces of that range that are actually contiguous.
*
* Calling ffs_blkrelease_start() will have created an entry
* that we will use.
*/
tp = trim_lookup(ump, devvp, bno, size, inum, key, OLD);
if (tp->size == 0) {
/*
* First block of a potential range, set block and size
* for the trim block.
*/
tp->bno = bno;
tp->size = size;
TAILQ_INSERT_HEAD(&tp->blklist, blkelm, blkreqlist);
return;
}
/*
* If this block is a continuation of the range (either
* follows at the end or preceeds in the front) then we
* add it to the front or back of the list and return.
*
* If it is not a continuation of the trim that we were
* building, using the REPLACE alloctype, we request that
* the old trim request (still in tp) be unhashed and a
* new range started (in ntp). The ffs_blkfree_sendtrim(tp)
* call causes the block range described by tp to be issued
* (and then tp to be freed).
*/
if (bno + numfrags(fs, size) == tp->bno) {
TAILQ_INSERT_HEAD(&tp->blklist, blkelm, blkreqlist);
tp->bno = bno;
tp->size += size;
return;
} else if (bno == tp->bno + numfrags(fs, tp->size)) {
TAILQ_INSERT_TAIL(&tp->blklist, blkelm, blkreqlist);
tp->size += size;
return;
}
ntp = trim_lookup(ump, devvp, bno, size, inum, key, REPLACE);
TAILQ_INSERT_HEAD(&ntp->blklist, blkelm, blkreqlist);
ffs_blkfree_sendtrim(tp);
}
#ifdef INVARIANTS
/*
* Verify allocation of a block or fragment. Returns true if block or
* fragment is allocated, false if it is free.
*/
static int
ffs_checkblk(struct inode *ip,
ufs2_daddr_t bno,
long size)
{
struct fs *fs;
struct cg *cgp;
struct buf *bp;
ufs1_daddr_t cgbno;
int i, error, frags, free;
u_int8_t *blksfree;
fs = ITOFS(ip);
if ((u_int)size > fs->fs_bsize || fragoff(fs, size) != 0) {
printf("bsize = %ld, size = %ld, fs = %s\n",
(long)fs->fs_bsize, size, fs->fs_fsmnt);
panic("ffs_checkblk: bad size");
}
if ((u_int)bno >= fs->fs_size)
panic("ffs_checkblk: bad block %jd", (intmax_t)bno);
error = ffs_getcg(fs, ITODEVVP(ip), dtog(fs, bno), 0, &bp, &cgp);
if (error)
panic("ffs_checkblk: cylinder group read failed");
blksfree = cg_blksfree(cgp);
cgbno = dtogd(fs, bno);
if (size == fs->fs_bsize) {
free = ffs_isblock(fs, blksfree, fragstoblks(fs, cgbno));
} else {
frags = numfrags(fs, size);
for (free = 0, i = 0; i < frags; i++)
if (isset(blksfree, cgbno + i))
free++;
if (free != 0 && free != frags)
panic("ffs_checkblk: partially free fragment");
}
brelse(bp);
return (!free);
}
#endif /* INVARIANTS */
/*
* Free an inode.
*/
int
ffs_vfree(struct vnode *pvp,
ino_t ino,
int mode)
{
struct ufsmount *ump;
if (DOINGSOFTDEP(pvp)) {
softdep_freefile(pvp, ino, mode);
return (0);
}
ump = VFSTOUFS(pvp->v_mount);
return (ffs_freefile(ump, ump->um_fs, ump->um_devvp, ino, mode, NULL));
}
/*
* Do the actual free operation.
* The specified inode is placed back in the free map.
*/
int
ffs_freefile(struct ufsmount *ump,
struct fs *fs,
struct vnode *devvp,
ino_t ino,
int mode,
struct workhead *wkhd)
{
struct cg *cgp;
struct buf *bp;
daddr_t dbn;
int error;
u_int cg;
u_int8_t *inosused;
struct cdev *dev;
ino_t cgino;
cg = ino_to_cg(fs, ino);
if (devvp->v_type == VREG) {
/* devvp is a snapshot */
MPASS(devvp->v_mount->mnt_data == ump);
dev = ump->um_devvp->v_rdev;
} else if (devvp->v_type == VCHR) {
/* devvp is a normal disk device */
dev = devvp->v_rdev;
} else {
bp = NULL;
return (0);
}
if (ino >= fs->fs_ipg * fs->fs_ncg)
panic("ffs_freefile: range: dev = %s, ino = %ju, fs = %s",
devtoname(dev), (uintmax_t)ino, fs->fs_fsmnt);
if ((error = ffs_getcg(fs, devvp, cg, GB_CVTENXIO, &bp, &cgp)) != 0) {
if (!ffs_fsfail_cleanup(ump, error) ||
!MOUNTEDSOFTDEP(UFSTOVFS(ump)) || devvp->v_type != VCHR)
return (error);
if (devvp->v_type == VREG)
dbn = fragstoblks(fs, cgtod(fs, cg));
else
dbn = fsbtodb(fs, cgtod(fs, cg));
error = getblkx(devvp, dbn, dbn, fs->fs_cgsize, 0, 0, 0, &bp);
KASSERT(error == 0, ("getblkx failed"));
softdep_setup_inofree(UFSTOVFS(ump), bp, ino, wkhd);
bp->b_flags |= B_RELBUF | B_NOCACHE;
bp->b_flags &= ~B_CACHE;
bawrite(bp);
return (error);
}
inosused = cg_inosused(cgp);
cgino = ino % fs->fs_ipg;
if (isclr(inosused, cgino)) {
printf("dev = %s, ino = %ju, fs = %s\n", devtoname(dev),
(uintmax_t)ino, fs->fs_fsmnt);
if (fs->fs_ronly == 0)
panic("ffs_freefile: freeing free inode");
}
clrbit(inosused, cgino);
if (cgino < cgp->cg_irotor)
cgp->cg_irotor = cgino;
cgp->cg_cs.cs_nifree++;
UFS_LOCK(ump);
fs->fs_cstotal.cs_nifree++;
fs->fs_cs(fs, cg).cs_nifree++;
if ((mode & IFMT) == IFDIR) {
cgp->cg_cs.cs_ndir--;
fs->fs_cstotal.cs_ndir--;
fs->fs_cs(fs, cg).cs_ndir--;
}
fs->fs_fmod = 1;
ACTIVECLEAR(fs, cg);
UFS_UNLOCK(ump);
if (MOUNTEDSOFTDEP(UFSTOVFS(ump)) && devvp->v_type == VCHR)
softdep_setup_inofree(UFSTOVFS(ump), bp, ino, wkhd);
bdwrite(bp);
return (0);
}
/*
* Check to see if a file is free.
* Used to check for allocated files in snapshots.
*/
int
ffs_checkfreefile(struct fs *fs,
struct vnode *devvp,
ino_t ino)
{
struct cg *cgp;
struct buf *bp;
int ret, error;
u_int cg;
u_int8_t *inosused;
cg = ino_to_cg(fs, ino);
if ((devvp->v_type != VREG) && (devvp->v_type != VCHR))
return (1);
if (ino >= fs->fs_ipg * fs->fs_ncg)
return (1);
if ((error = ffs_getcg(fs, devvp, cg, 0, &bp, &cgp)) != 0)
return (1);
inosused = cg_inosused(cgp);
ino %= fs->fs_ipg;
ret = isclr(inosused, ino);
brelse(bp);
return (ret);
}
/*
* 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 ufs1_daddr_t
ffs_mapsearch(struct fs *fs,
struct cg *cgp,
ufs2_daddr_t bpref,
int allocsiz)
{
ufs1_daddr_t bno;
int start, len, loc, i;
int blk, field, subfield, pos;
u_int8_t *blksfree;
/*
* 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;
blksfree = cg_blksfree(cgp);
len = howmany(fs->fs_fpg, NBBY) - start;
loc = scanc((u_int)len, (u_char *)&blksfree[start],
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 *)&blksfree[0],
fragtbl[fs->fs_frag],
(u_char)(1 << (allocsiz - 1 + (fs->fs_frag % NBBY))));
if (loc == 0) {
printf("start = %d, len = %d, fs = %s\n",
start, len, fs->fs_fsmnt);
panic("ffs_alloccg: map corrupted");
/* NOTREACHED */
}
}
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, blksfree, 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;
}
}
printf("bno = %lu, fs = %s\n", (u_long)bno, fs->fs_fsmnt);
panic("ffs_alloccg: block not in map");
return (-1);
}
static const struct statfs *
ffs_getmntstat(struct vnode *devvp)
{
if (devvp->v_type == VCHR)
return (&devvp->v_rdev->si_mountpt->mnt_stat);
return (ffs_getmntstat(VFSTOUFS(devvp->v_mount)->um_devvp));
}
/*
* Fetch and verify a cylinder group.
*/
int
ffs_getcg(struct fs *fs,
struct vnode *devvp,
u_int cg,
int flags,
struct buf **bpp,
struct cg **cgpp)
{
struct buf *bp;
struct cg *cgp;
const struct statfs *sfs;
daddr_t blkno;
int error;
*bpp = NULL;
*cgpp = NULL;
if ((fs->fs_metackhash & CK_CYLGRP) != 0)
flags |= GB_CKHASH;
if (devvp->v_type == VREG)
blkno = fragstoblks(fs, cgtod(fs, cg));
else
blkno = fsbtodb(fs, cgtod(fs, cg));
error = breadn_flags(devvp, blkno, blkno, (int)fs->fs_cgsize, NULL,
NULL, 0, NOCRED, flags, ffs_ckhash_cg, &bp);
if (error != 0)
return (error);
cgp = (struct cg *)bp->b_data;
if ((fs->fs_metackhash & CK_CYLGRP) != 0 &&
(bp->b_flags & B_CKHASH) != 0 &&
cgp->cg_ckhash != bp->b_ckhash) {
sfs = ffs_getmntstat(devvp);
printf("UFS %s%s (%s) cylinder checksum failed: cg %u, cgp: "
"0x%x != bp: 0x%jx\n",
devvp->v_type == VCHR ? "" : "snapshot of ",
sfs->f_mntfromname, sfs->f_mntonname,
cg, cgp->cg_ckhash, (uintmax_t)bp->b_ckhash);
bp->b_flags &= ~B_CKHASH;
bp->b_flags |= B_INVAL | B_NOCACHE;
brelse(bp);
return (EIO);
}
if (!cg_chkmagic(cgp) || cgp->cg_cgx != cg) {
sfs = ffs_getmntstat(devvp);
printf("UFS %s%s (%s)",
devvp->v_type == VCHR ? "" : "snapshot of ",
sfs->f_mntfromname, sfs->f_mntonname);
if (!cg_chkmagic(cgp))
printf(" cg %u: bad magic number 0x%x should be 0x%x\n",
cg, cgp->cg_magic, CG_MAGIC);
else
printf(": wrong cylinder group cg %u != cgx %u\n", cg,
cgp->cg_cgx);
bp->b_flags &= ~B_CKHASH;
bp->b_flags |= B_INVAL | B_NOCACHE;
brelse(bp);
return (EIO);
}
bp->b_flags &= ~B_CKHASH;
bp->b_xflags |= BX_BKGRDWRITE;
/*
* If we are using check hashes on the cylinder group then we want
* to limit changing the cylinder group time to when we are actually
* going to write it to disk so that its check hash remains correct
* in memory. If the CK_CYLGRP flag is set the time is updated in
* ffs_bufwrite() as the buffer is queued for writing. Otherwise we
* update the time here as we have done historically.
*/
if ((fs->fs_metackhash & CK_CYLGRP) != 0)
bp->b_xflags |= BX_CYLGRP;
else
cgp->cg_old_time = cgp->cg_time = time_second;
*bpp = bp;
*cgpp = cgp;
return (0);
}
static void
ffs_ckhash_cg(struct buf *bp)
{
uint32_t ckhash;
struct cg *cgp;
cgp = (struct cg *)bp->b_data;
ckhash = cgp->cg_ckhash;
cgp->cg_ckhash = 0;
bp->b_ckhash = calculate_crc32c(~0L, bp->b_data, bp->b_bcount);
cgp->cg_ckhash = ckhash;
}
/*
* Fserr prints the name of a filesystem with an error diagnostic.
*
* The form of the error message is:
* fs: error message
*/
void
ffs_fserr(struct fs *fs,
ino_t inum,
char *cp)
{
struct thread *td = curthread; /* XXX */
struct proc *p = td->td_proc;
log(LOG_ERR, "pid %d (%s), uid %d inumber %ju on %s: %s\n",
p->p_pid, p->p_comm, td->td_ucred->cr_uid, (uintmax_t)inum,
fs->fs_fsmnt, cp);
}
/*
* This function provides the capability for the fsck program to
* update an active filesystem. Fourteen operations are provided:
*
* adjrefcnt(inode, amt) - adjusts the reference count on the
* specified inode by the specified amount. Under normal
* operation the count should always go down. Decrementing
* the count to zero will cause the inode to be freed.
* adjblkcnt(inode, amt) - adjust the number of blocks used by the
* inode by the specified amount.
* setsize(inode, size) - set the size of the inode to the
* specified size.
* adjndir, adjbfree, adjifree, adjffree, adjnumclusters(amt) -
* adjust the superblock summary.
* freedirs(inode, count) - directory inodes [inode..inode + count - 1]
* are marked as free. Inodes should never have to be marked
* as in use.
* freefiles(inode, count) - file inodes [inode..inode + count - 1]
* are marked as free. Inodes should never have to be marked
* as in use.
* freeblks(blockno, size) - blocks [blockno..blockno + size - 1]
* are marked as free. Blocks should never have to be marked
* as in use.
* setflags(flags, set/clear) - the fs_flags field has the specified
* flags set (second parameter +1) or cleared (second parameter -1).
* setcwd(dirinode) - set the current directory to dirinode in the
* filesystem associated with the snapshot.
* setdotdot(oldvalue, newvalue) - Verify that the inode number for ".."
* in the current directory is oldvalue then change it to newvalue.
* unlink(nameptr, oldvalue) - Verify that the inode number associated
* with nameptr in the current directory is oldvalue then unlink it.
*/
static int sysctl_ffs_fsck(SYSCTL_HANDLER_ARGS);
SYSCTL_PROC(_vfs_ffs, FFS_ADJ_REFCNT, adjrefcnt,
CTLFLAG_WR | CTLTYPE_STRUCT | CTLFLAG_NEEDGIANT,
0, 0, sysctl_ffs_fsck, "S,fsck",
"Adjust Inode Reference Count");
static SYSCTL_NODE(_vfs_ffs, FFS_ADJ_BLKCNT, adjblkcnt,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Adjust Inode Used Blocks Count");
static SYSCTL_NODE(_vfs_ffs, FFS_SET_SIZE, setsize,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Set the inode size");
static SYSCTL_NODE(_vfs_ffs, FFS_ADJ_NDIR, adjndir,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Adjust number of directories");
static SYSCTL_NODE(_vfs_ffs, FFS_ADJ_NBFREE, adjnbfree,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Adjust number of free blocks");
static SYSCTL_NODE(_vfs_ffs, FFS_ADJ_NIFREE, adjnifree,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Adjust number of free inodes");
static SYSCTL_NODE(_vfs_ffs, FFS_ADJ_NFFREE, adjnffree,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Adjust number of free frags");
static SYSCTL_NODE(_vfs_ffs, FFS_ADJ_NUMCLUSTERS, adjnumclusters,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Adjust number of free clusters");
static SYSCTL_NODE(_vfs_ffs, FFS_DIR_FREE, freedirs,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Free Range of Directory Inodes");
static SYSCTL_NODE(_vfs_ffs, FFS_FILE_FREE, freefiles,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Free Range of File Inodes");
static SYSCTL_NODE(_vfs_ffs, FFS_BLK_FREE, freeblks,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Free Range of Blocks");
static SYSCTL_NODE(_vfs_ffs, FFS_SET_FLAGS, setflags,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Change Filesystem Flags");
static SYSCTL_NODE(_vfs_ffs, FFS_SET_CWD, setcwd,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Set Current Working Directory");
static SYSCTL_NODE(_vfs_ffs, FFS_SET_DOTDOT, setdotdot,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Change Value of .. Entry");
static SYSCTL_NODE(_vfs_ffs, FFS_UNLINK, unlink,
CTLFLAG_WR | CTLFLAG_NEEDGIANT, sysctl_ffs_fsck,
"Unlink a Duplicate Name");
#ifdef DIAGNOSTIC
static int fsckcmds = 0;
SYSCTL_INT(_debug, OID_AUTO, ffs_fsckcmds, CTLFLAG_RW, &fsckcmds, 0,
"print out fsck_ffs-based filesystem update commands");
#endif /* DIAGNOSTIC */
static int
sysctl_ffs_fsck(SYSCTL_HANDLER_ARGS)
{
struct thread *td = curthread;
struct fsck_cmd cmd;
struct ufsmount *ump;
struct vnode *vp, *dvp, *fdvp;
struct inode *ip, *dp;
struct mount *mp;
struct fs *fs;
struct pwd *pwd;
ufs2_daddr_t blkno;
long blkcnt, blksize;
u_long key;
struct file *fp;
cap_rights_t rights;
int filetype, error;
if (req->newptr == NULL || req->newlen > sizeof(cmd))
return (EBADRPC);
if ((error = SYSCTL_IN(req, &cmd, sizeof(cmd))) != 0)
return (error);
if (cmd.version != FFS_CMD_VERSION)
return (ERPCMISMATCH);
if ((error = getvnode(td, cmd.handle,
cap_rights_init_one(&rights, CAP_FSCK), &fp)) != 0)
return (error);
vp = fp->f_vnode;
if (vp->v_type != VREG && vp->v_type != VDIR) {
fdrop(fp, td);
return (EINVAL);
}
vn_start_write(vp, &mp, V_WAIT);
if (mp == NULL ||
strncmp(mp->mnt_stat.f_fstypename, "ufs", MFSNAMELEN)) {
vn_finished_write(mp);
fdrop(fp, td);
return (EINVAL);
}
ump = VFSTOUFS(mp);
if (mp->mnt_flag & MNT_RDONLY) {
vn_finished_write(mp);
fdrop(fp, td);
return (EROFS);
}
fs = ump->um_fs;
filetype = IFREG;
switch (oidp->oid_number) {
case FFS_SET_FLAGS:
#ifdef DIAGNOSTIC
if (fsckcmds)
printf("%s: %s flags\n", mp->mnt_stat.f_mntonname,
cmd.size > 0 ? "set" : "clear");
#endif /* DIAGNOSTIC */
if (cmd.size > 0)
fs->fs_flags |= (long)cmd.value;
else
fs->fs_flags &= ~(long)cmd.value;
break;
case FFS_ADJ_REFCNT:
#ifdef DIAGNOSTIC
if (fsckcmds) {
printf("%s: adjust inode %jd link count by %jd\n",
mp->mnt_stat.f_mntonname, (intmax_t)cmd.value,
(intmax_t)cmd.size);
}
#endif /* DIAGNOSTIC */
if ((error = ffs_vget(mp, (ino_t)cmd.value, LK_EXCLUSIVE, &vp)))
break;
ip = VTOI(vp);
ip->i_nlink += cmd.size;
DIP_SET(ip, i_nlink, ip->i_nlink);
ip->i_effnlink += cmd.size;
UFS_INODE_SET_FLAG(ip, IN_CHANGE | IN_MODIFIED);
error = ffs_update(vp, 1);
if (DOINGSOFTDEP(vp))
softdep_change_linkcnt(ip);
vput(vp);
break;
case FFS_ADJ_BLKCNT:
#ifdef DIAGNOSTIC
if (fsckcmds) {
printf("%s: adjust inode %jd block count by %jd\n",
mp->mnt_stat.f_mntonname, (intmax_t)cmd.value,
(intmax_t)cmd.size);
}
#endif /* DIAGNOSTIC */
if ((error = ffs_vget(mp, (ino_t)cmd.value, LK_EXCLUSIVE, &vp)))
break;
ip = VTOI(vp);
DIP_SET(ip, i_blocks, DIP(ip, i_blocks) + cmd.size);
UFS_INODE_SET_FLAG(ip, IN_CHANGE | IN_MODIFIED);
error = ffs_update(vp, 1);
vput(vp);
break;
case FFS_SET_SIZE:
#ifdef DIAGNOSTIC
if (fsckcmds) {
printf("%s: set inode %jd size to %jd\n",
mp->mnt_stat.f_mntonname, (intmax_t)cmd.value,
(intmax_t)cmd.size);
}
#endif /* DIAGNOSTIC */
if ((error = ffs_vget(mp, (ino_t)cmd.value, LK_EXCLUSIVE, &vp)))
break;
ip = VTOI(vp);
DIP_SET(ip, i_size, cmd.size);
UFS_INODE_SET_FLAG(ip, IN_SIZEMOD | IN_CHANGE | IN_MODIFIED);
error = ffs_update(vp, 1);
vput(vp);
break;
case FFS_DIR_FREE:
filetype = IFDIR;
/* fall through */
case FFS_FILE_FREE:
#ifdef DIAGNOSTIC
if (fsckcmds) {
if (cmd.size == 1)
printf("%s: free %s inode %ju\n",
mp->mnt_stat.f_mntonname,
filetype == IFDIR ? "directory" : "file",
(uintmax_t)cmd.value);
else
printf("%s: free %s inodes %ju-%ju\n",
mp->mnt_stat.f_mntonname,
filetype == IFDIR ? "directory" : "file",
(uintmax_t)cmd.value,
(uintmax_t)(cmd.value + cmd.size - 1));
}
#endif /* DIAGNOSTIC */
while (cmd.size > 0) {
if ((error = ffs_freefile(ump, fs, ump->um_devvp,
cmd.value, filetype, NULL)))
break;
cmd.size -= 1;
cmd.value += 1;
}
break;
case FFS_BLK_FREE:
#ifdef DIAGNOSTIC
if (fsckcmds) {
if (cmd.size == 1)
printf("%s: free block %jd\n",
mp->mnt_stat.f_mntonname,
(intmax_t)cmd.value);
else
printf("%s: free blocks %jd-%jd\n",
mp->mnt_stat.f_mntonname,
(intmax_t)cmd.value,
(intmax_t)cmd.value + cmd.size - 1);
}
#endif /* DIAGNOSTIC */
blkno = cmd.value;
blkcnt = cmd.size;
blksize = fs->fs_frag - (blkno % fs->fs_frag);
key = ffs_blkrelease_start(ump, ump->um_devvp, UFS_ROOTINO);
while (blkcnt > 0) {
if (blkcnt < blksize)
blksize = blkcnt;
ffs_blkfree(ump, fs, ump->um_devvp, blkno,
blksize * fs->fs_fsize, UFS_ROOTINO,
VDIR, NULL, key);
blkno += blksize;
blkcnt -= blksize;
blksize = fs->fs_frag;
}
ffs_blkrelease_finish(ump, key);
break;
/*
* Adjust superblock summaries. fsck(8) is expected to
* submit deltas when necessary.
*/
case FFS_ADJ_NDIR:
#ifdef DIAGNOSTIC
if (fsckcmds) {
printf("%s: adjust number of directories by %jd\n",
mp->mnt_stat.f_mntonname, (intmax_t)cmd.value);
}
#endif /* DIAGNOSTIC */
fs->fs_cstotal.cs_ndir += cmd.value;
break;
case FFS_ADJ_NBFREE:
#ifdef DIAGNOSTIC
if (fsckcmds) {
printf("%s: adjust number of free blocks by %+jd\n",
mp->mnt_stat.f_mntonname, (intmax_t)cmd.value);
}
#endif /* DIAGNOSTIC */
fs->fs_cstotal.cs_nbfree += cmd.value;
break;
case FFS_ADJ_NIFREE:
#ifdef DIAGNOSTIC
if (fsckcmds) {
printf("%s: adjust number of free inodes by %+jd\n",
mp->mnt_stat.f_mntonname, (intmax_t)cmd.value);
}
#endif /* DIAGNOSTIC */
fs->fs_cstotal.cs_nifree += cmd.value;
break;
case FFS_ADJ_NFFREE:
#ifdef DIAGNOSTIC
if (fsckcmds) {
printf("%s: adjust number of free frags by %+jd\n",
mp->mnt_stat.f_mntonname, (intmax_t)cmd.value);
}
#endif /* DIAGNOSTIC */
fs->fs_cstotal.cs_nffree += cmd.value;
break;
case FFS_ADJ_NUMCLUSTERS:
#ifdef DIAGNOSTIC
if (fsckcmds) {
printf("%s: adjust number of free clusters by %+jd\n",
mp->mnt_stat.f_mntonname, (intmax_t)cmd.value);
}
#endif /* DIAGNOSTIC */
fs->fs_cstotal.cs_numclusters += cmd.value;
break;
case FFS_SET_CWD:
#ifdef DIAGNOSTIC
if (fsckcmds) {
printf("%s: set current directory to inode %jd\n",
mp->mnt_stat.f_mntonname, (intmax_t)cmd.value);
}
#endif /* DIAGNOSTIC */
if ((error = ffs_vget(mp, (ino_t)cmd.value, LK_SHARED, &vp)))
break;
AUDIT_ARG_VNODE1(vp);
if ((error = change_dir(vp, td)) != 0) {
vput(vp);
break;
}
VOP_UNLOCK(vp);
pwd_chdir(td, vp);
break;
case FFS_SET_DOTDOT:
#ifdef DIAGNOSTIC
if (fsckcmds) {
printf("%s: change .. in cwd from %jd to %jd\n",
mp->mnt_stat.f_mntonname, (intmax_t)cmd.value,
(intmax_t)cmd.size);
}
#endif /* DIAGNOSTIC */
/*
* First we have to get and lock the parent directory
* to which ".." points.
*/
error = ffs_vget(mp, (ino_t)cmd.value, LK_EXCLUSIVE, &fdvp);
if (error)
break;
/*
* Now we get and lock the child directory containing "..".
*/
pwd = pwd_hold(td);
dvp = pwd->pwd_cdir;
if ((error = vget(dvp, LK_EXCLUSIVE)) != 0) {
vput(fdvp);
pwd_drop(pwd);
break;
}
dp = VTOI(dvp);
SET_I_OFFSET(dp, 12); /* XXX mastertemplate.dot_reclen */
error = ufs_dirrewrite(dp, VTOI(fdvp), (ino_t)cmd.size,
DT_DIR, 0);
cache_purge(fdvp);
cache_purge(dvp);
vput(dvp);
vput(fdvp);
pwd_drop(pwd);
break;
case FFS_UNLINK:
#ifdef DIAGNOSTIC
if (fsckcmds) {
char buf[32];
if (copyinstr((char *)(intptr_t)cmd.value, buf,32,NULL))
strncpy(buf, "Name_too_long", 32);
printf("%s: unlink %s (inode %jd)\n",
mp->mnt_stat.f_mntonname, buf, (intmax_t)cmd.size);
}
#endif /* DIAGNOSTIC */
/*
* kern_funlinkat will do its own start/finish writes and
* they do not nest, so drop ours here. Setting mp == NULL
* indicates that vn_finished_write is not needed down below.
*/
vn_finished_write(mp);
mp = NULL;
error = kern_funlinkat(td, AT_FDCWD,
(char *)(intptr_t)cmd.value, FD_NONE, UIO_USERSPACE,
0, (ino_t)cmd.size);
break;
default:
#ifdef DIAGNOSTIC
if (fsckcmds) {
printf("Invalid request %d from fsck\n",
oidp->oid_number);
}
#endif /* DIAGNOSTIC */
error = EINVAL;
break;
}
fdrop(fp, td);
vn_finished_write(mp);
return (error);
}