freebsd-nq/sbin/tunefs/tunefs.c

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/*-
* SPDX-License-Identifier: BSD-3-Clause
*
* Copyright (c) 1983, 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.
*/
#if 0
#ifndef lint
static const char copyright[] =
"@(#) Copyright (c) 1983, 1993\n\
The Regents of the University of California. All rights reserved.\n";
#endif /* not lint */
#ifndef lint
static char sccsid[] = "@(#)tunefs.c 8.2 (Berkeley) 4/19/94";
#endif /* not lint */
#endif
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
/*
* tunefs: change layout parameters to an existing file system.
*/
#include <sys/param.h>
#include <sys/mount.h>
#include <sys/disklabel.h>
#include <sys/stat.h>
#include <ufs/ufs/ufsmount.h>
This commit adds basic support for the UFS2 filesystem. The UFS2 filesystem expands the inode to 256 bytes to make space for 64-bit block pointers. It also adds a file-creation time field, an ability to use jumbo blocks per inode to allow extent like pointer density, and space for extended attributes (up to twice the filesystem block size worth of attributes, e.g., on a 16K filesystem, there is space for 32K of attributes). UFS2 fully supports and runs existing UFS1 filesystems. New filesystems built using newfs can be built in either UFS1 or UFS2 format using the -O option. In this commit UFS1 is the default format, so if you want to build UFS2 format filesystems, you must specify -O 2. This default will be changed to UFS2 when UFS2 proves itself to be stable. In this commit the boot code for reading UFS2 filesystems is not compiled (see /sys/boot/common/ufsread.c) as there is insufficient space in the boot block. Once the size of the boot block is increased, this code can be defined. Things to note: the definition of SBSIZE has changed to SBLOCKSIZE. The header file <ufs/ufs/dinode.h> must be included before <ufs/ffs/fs.h> so as to get the definitions of ufs2_daddr_t and ufs_lbn_t. Still TODO: Verify that the first level bootstraps work for all the architectures. Convert the utility ffsinfo to understand UFS2 and test growfs. Add support for the extended attribute storage. Update soft updates to ensure integrity of extended attribute storage. Switch the current extended attribute interfaces to use the extended attribute storage. Add the extent like functionality (framework is there, but is currently never used). Sponsored by: DARPA & NAI Labs. Reviewed by: Poul-Henning Kamp <phk@freebsd.org>
2002-06-21 06:18:05 +00:00
#include <ufs/ufs/dinode.h>
#include <ufs/ffs/fs.h>
#include <ufs/ufs/dir.h>
#include <ctype.h>
#include <err.h>
#include <fcntl.h>
#include <fstab.h>
#include <libufs.h>
#include <mntopts.h>
#include <paths.h>
#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
#include <string.h>
#include <time.h>
#include <unistd.h>
/* the optimization warning string template */
#define OPTWARN "should optimize for %s with minfree %s %d%%"
static int blocks;
static char clrbuf[MAXBSIZE];
static struct uufsd disk;
#define sblock disk.d_fs
static void usage(void);
static void printfs(void);
static int journal_alloc(int64_t size);
static void journal_clear(void);
static void sbdirty(void);
int
main(int argc, char *argv[])
{
const char *avalue, *jvalue, *Jvalue, *Lvalue, *lvalue, *Nvalue, *nvalue;
const char *tvalue;
const char *special, *on;
const char *name;
int active;
int Aflag, aflag, eflag, evalue, fflag, fvalue, jflag, Jflag, kflag;
int kvalue, Lflag, lflag, mflag, mvalue, Nflag, nflag, oflag, ovalue;
int pflag, sflag, svalue, Svalue, tflag;
int ch, found_arg, i;
int iovlen = 0;
const char *chg[2];
struct statfs stfs;
struct iovec *iov = NULL;
char errmsg[255] = {0};
if (argc < 3)
usage();
Aflag = aflag = eflag = fflag = jflag = Jflag = kflag = Lflag = 0;
lflag = mflag = Nflag = nflag = oflag = pflag = sflag = tflag = 0;
avalue = jvalue = Jvalue = Lvalue = lvalue = Nvalue = nvalue = NULL;
evalue = fvalue = mvalue = ovalue = svalue = Svalue = 0;
active = 0;
found_arg = 0; /* At least one arg is required. */
while ((ch = getopt(argc, argv, "Aa:e:f:j:J:k:L:l:m:N:n:o:ps:S:t:"))
!= -1)
switch (ch) {
case 'A':
found_arg = 1;
Aflag++;
break;
case 'a':
found_arg = 1;
name = "POSIX.1e ACLs";
avalue = optarg;
if (strcmp(avalue, "enable") &&
strcmp(avalue, "disable")) {
errx(10, "bad %s (options are %s)",
name, "`enable' or `disable'");
}
aflag = 1;
break;
case 'e':
found_arg = 1;
name = "maximum blocks per file in a cylinder group";
evalue = atoi(optarg);
if (evalue < 1)
errx(10, "%s must be >= 1 (was %s)",
name, optarg);
eflag = 1;
break;
case 'f':
found_arg = 1;
name = "average file size";
fvalue = atoi(optarg);
if (fvalue < 1)
errx(10, "%s must be >= 1 (was %s)",
name, optarg);
fflag = 1;
break;
case 'j':
found_arg = 1;
name = "softdep journaled file system";
jvalue = optarg;
if (strcmp(jvalue, "enable") &&
strcmp(jvalue, "disable")) {
errx(10, "bad %s (options are %s)",
name, "`enable' or `disable'");
}
jflag = 1;
break;
case 'J':
found_arg = 1;
name = "gjournaled file system";
Jvalue = optarg;
if (strcmp(Jvalue, "enable") &&
strcmp(Jvalue, "disable")) {
errx(10, "bad %s (options are %s)",
name, "`enable' or `disable'");
}
Jflag = 1;
break;
case 'k':
found_arg = 1;
name = "space to hold for metadata blocks";
kvalue = atoi(optarg);
if (kvalue < 0)
errx(10, "bad %s (%s)", name, optarg);
kflag = 1;
break;
case 'L':
found_arg = 1;
name = "volume label";
Lvalue = optarg;
i = -1;
while (isalnum(Lvalue[++i]));
if (Lvalue[i] != '\0') {
errx(10,
"bad %s. Valid characters are alphanumerics.",
name);
}
if (strlen(Lvalue) >= MAXVOLLEN) {
errx(10, "bad %s. Length is longer than %d.",
name, MAXVOLLEN - 1);
}
Lflag = 1;
break;
case 'l':
found_arg = 1;
name = "multilabel MAC file system";
lvalue = optarg;
if (strcmp(lvalue, "enable") &&
strcmp(lvalue, "disable")) {
errx(10, "bad %s (options are %s)",
name, "`enable' or `disable'");
}
lflag = 1;
break;
case 'm':
found_arg = 1;
name = "minimum percentage of free space";
mvalue = atoi(optarg);
if (mvalue < 0 || mvalue > 99)
errx(10, "bad %s (%s)", name, optarg);
mflag = 1;
break;
case 'N':
found_arg = 1;
name = "NFSv4 ACLs";
Nvalue = optarg;
if (strcmp(Nvalue, "enable") &&
strcmp(Nvalue, "disable")) {
errx(10, "bad %s (options are %s)",
name, "`enable' or `disable'");
}
Nflag = 1;
break;
case 'n':
found_arg = 1;
name = "soft updates";
nvalue = optarg;
if (strcmp(nvalue, "enable") != 0 &&
strcmp(nvalue, "disable") != 0) {
errx(10, "bad %s (options are %s)",
name, "`enable' or `disable'");
}
nflag = 1;
break;
case 'o':
found_arg = 1;
name = "optimization preference";
if (strcmp(optarg, "space") == 0)
ovalue = FS_OPTSPACE;
else if (strcmp(optarg, "time") == 0)
ovalue = FS_OPTTIME;
else
errx(10,
"bad %s (options are `space' or `time')",
name);
oflag = 1;
break;
case 'p':
found_arg = 1;
pflag = 1;
break;
case 's':
found_arg = 1;
name = "expected number of files per directory";
svalue = atoi(optarg);
if (svalue < 1)
errx(10, "%s must be >= 1 (was %s)",
name, optarg);
sflag = 1;
break;
case 'S':
found_arg = 1;
name = "Softdep Journal Size";
Svalue = atoi(optarg);
if (Svalue < SUJ_MIN)
errx(10, "%s must be >= %d (was %s)",
name, SUJ_MIN, optarg);
break;
case 't':
found_arg = 1;
name = "trim";
tvalue = optarg;
if (strcmp(tvalue, "enable") != 0 &&
strcmp(tvalue, "disable") != 0) {
errx(10, "bad %s (options are %s)",
name, "`enable' or `disable'");
}
tflag = 1;
break;
default:
usage();
}
argc -= optind;
argv += optind;
if (found_arg == 0 || argc != 1)
usage();
on = special = argv[0];
if (ufs_disk_fillout(&disk, special) == -1)
goto err;
if (disk.d_name != special) {
if (statfs(special, &stfs) != 0)
warn("Can't stat %s", special);
if (strcmp(special, stfs.f_mntonname) == 0)
active = 1;
}
if (pflag) {
printfs();
exit(0);
}
if (Lflag) {
name = "volume label";
strncpy(sblock.fs_volname, Lvalue, MAXVOLLEN);
}
if (aflag) {
name = "POSIX.1e ACLs";
if (strcmp(avalue, "enable") == 0) {
if (sblock.fs_flags & FS_ACLS) {
warnx("%s remains unchanged as enabled", name);
} else if (sblock.fs_flags & FS_NFS4ACLS) {
warnx("%s and NFSv4 ACLs are mutually "
"exclusive", name);
} else {
sblock.fs_flags |= FS_ACLS;
warnx("%s set", name);
}
} else if (strcmp(avalue, "disable") == 0) {
if ((~sblock.fs_flags & FS_ACLS) ==
FS_ACLS) {
warnx("%s remains unchanged as disabled",
name);
} else {
sblock.fs_flags &= ~FS_ACLS;
warnx("%s cleared", name);
}
}
}
if (eflag) {
name = "maximum blocks per file in a cylinder group";
if (sblock.fs_maxbpg == evalue)
warnx("%s remains unchanged as %d", name, evalue);
else {
warnx("%s changes from %d to %d",
name, sblock.fs_maxbpg, evalue);
sblock.fs_maxbpg = evalue;
}
}
Directory layout preference improvements from Grigoriy Orlov <gluk@ptci.ru>. His description of the problem and solution follow. My own tests show speedups on typical filesystem intensive workloads of 5% to 12% which is very impressive considering the small amount of code change involved. ------ One day I noticed that some file operations run much faster on small file systems then on big ones. I've looked at the ffs algorithms, thought about them, and redesigned the dirpref algorithm. First I want to describe the results of my tests. These results are old and I have improved the algorithm after these tests were done. Nevertheless they show how big the perfomance speedup may be. I have done two file/directory intensive tests on a two OpenBSD systems with old and new dirpref algorithm. The first test is "tar -xzf ports.tar.gz", the second is "rm -rf ports". The ports.tar.gz file is the ports collection from the OpenBSD 2.8 release. It contains 6596 directories and 13868 files. The test systems are: 1. Celeron-450, 128Mb, two IDE drives, the system at wd0, file system for test is at wd1. Size of test file system is 8 Gb, number of cg=991, size of cg is 8m, block size = 8k, fragment size = 1k OpenBSD-current from Dec 2000 with BUFCACHEPERCENT=35 2. PIII-600, 128Mb, two IBM DTLA-307045 IDE drives at i815e, the system at wd0, file system for test is at wd1. Size of test file system is 40 Gb, number of cg=5324, size of cg is 8m, block size = 8k, fragment size = 1k OpenBSD-current from Dec 2000 with BUFCACHEPERCENT=50 You can get more info about the test systems and methods at: http://www.ptci.ru/gluk/dirpref/old/dirpref.html Test Results tar -xzf ports.tar.gz rm -rf ports mode old dirpref new dirpref speedup old dirprefnew dirpref speedup First system normal 667 472 1.41 477 331 1.44 async 285 144 1.98 130 14 9.29 sync 768 616 1.25 477 334 1.43 softdep 413 252 1.64 241 38 6.34 Second system normal 329 81 4.06 263.5 93.5 2.81 async 302 25.7 11.75 112 2.26 49.56 sync 281 57.0 4.93 263 90.5 2.9 softdep 341 40.6 8.4 284 4.76 59.66 "old dirpref" and "new dirpref" columns give a test time in seconds. speedup - speed increasement in times, ie. old dirpref / new dirpref. ------ Algorithm description The old dirpref algorithm is described in comments: /* * Find a cylinder to place a directory. * * The policy implemented by this algorithm is to select from * among those cylinder groups with above the average number of * free inodes, the one with the smallest number of directories. */ A new directory is allocated in a different cylinder groups than its parent directory resulting in a directory tree that is spreaded across all the cylinder groups. This spreading out results in a non-optimal access to the directories and files. When we have a small filesystem it is not a problem but when the filesystem is big then perfomance degradation becomes very apparent. What I mean by a big file system ? 1. A big filesystem is a filesystem which occupy 20-30 or more percent of total drive space, i.e. first and last cylinder are physically located relatively far from each other. 2. It has a relatively large number of cylinder groups, for example more cylinder groups than 50% of the buffers in the buffer cache. The first results in long access times, while the second results in many buffers being used by metadata operations. Such operations use cylinder group blocks and on-disk inode blocks. The cylinder group block (fs->fs_cblkno) contains struct cg, inode and block bit maps. It is 2k in size for the default filesystem parameters. If new and parent directories are located in different cylinder groups then the system performs more input/output operations and uses more buffers. On filesystems with many cylinder groups, lots of cache buffers are used for metadata operations. My solution for this problem is very simple. I allocate many directories in one cylinder group. I also do some things, so that the new allocation method does not cause excessive fragmentation and all directory inodes will not be located at a location far from its file's inodes and data. The algorithm is: /* * 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. */ My early versions of dirpref give me a good results for a wide range of file operations and different filesystem capacities except one case: those applications that create their entire directory structure first and only later fill this structure with files. My solution for such and similar cases is to limit a number of directories which may be created one after another in the same cylinder group without intervening file creations. For this purpose, I allocate an array of counters at mount time. This array is linked to the superblock fs->fs_contigdirs[cg]. Each time a directory is created the counter increases and each time a file is created the counter decreases. A 60Gb filesystem with 8mb/cg requires 10kb of memory for the counters array. The maxcontigdirs is a maximum number of directories which may be created without an intervening file creation. I found in my tests that the best performance occurs when I restrict the number of directories in one cylinder group such that all its files may be located in the same cylinder group. There may be some deterioration in performance if all the file inodes are in the same cylinder group as its containing directory, but their data partially resides in a different cylinder group. The maxcontigdirs value is calculated to try to prevent this condition. Since there is no way to know how many files and directories will be allocated later I added two optimization parameters in superblock/tunefs. They are: int32_t fs_avgfilesize; /* expected average file size */ int32_t fs_avgfpdir; /* expected # of files per directory */ These parameters have reasonable defaults but may be tweeked for special uses of a filesystem. They are only necessary in rare cases like better tuning a filesystem being used to store a squid cache. I have been using this algorithm for about 3 months. I have done a lot of testing on filesystems with different capacities, average filesize, average number of files per directory, and so on. I think this algorithm has no negative impact on filesystem perfomance. It works better than the default one in all cases. The new dirpref will greatly improve untarring/removing/coping of big directories, decrease load on cvs servers and much more. The new dirpref doesn't speedup a compilation process, but also doesn't slow it down. Obtained from: Grigoriy Orlov <gluk@ptci.ru>
2001-04-10 08:38:59 +00:00
if (fflag) {
name = "average file size";
2010-02-11 06:33:35 +00:00
if (sblock.fs_avgfilesize == (unsigned)fvalue) {
Directory layout preference improvements from Grigoriy Orlov <gluk@ptci.ru>. His description of the problem and solution follow. My own tests show speedups on typical filesystem intensive workloads of 5% to 12% which is very impressive considering the small amount of code change involved. ------ One day I noticed that some file operations run much faster on small file systems then on big ones. I've looked at the ffs algorithms, thought about them, and redesigned the dirpref algorithm. First I want to describe the results of my tests. These results are old and I have improved the algorithm after these tests were done. Nevertheless they show how big the perfomance speedup may be. I have done two file/directory intensive tests on a two OpenBSD systems with old and new dirpref algorithm. The first test is "tar -xzf ports.tar.gz", the second is "rm -rf ports". The ports.tar.gz file is the ports collection from the OpenBSD 2.8 release. It contains 6596 directories and 13868 files. The test systems are: 1. Celeron-450, 128Mb, two IDE drives, the system at wd0, file system for test is at wd1. Size of test file system is 8 Gb, number of cg=991, size of cg is 8m, block size = 8k, fragment size = 1k OpenBSD-current from Dec 2000 with BUFCACHEPERCENT=35 2. PIII-600, 128Mb, two IBM DTLA-307045 IDE drives at i815e, the system at wd0, file system for test is at wd1. Size of test file system is 40 Gb, number of cg=5324, size of cg is 8m, block size = 8k, fragment size = 1k OpenBSD-current from Dec 2000 with BUFCACHEPERCENT=50 You can get more info about the test systems and methods at: http://www.ptci.ru/gluk/dirpref/old/dirpref.html Test Results tar -xzf ports.tar.gz rm -rf ports mode old dirpref new dirpref speedup old dirprefnew dirpref speedup First system normal 667 472 1.41 477 331 1.44 async 285 144 1.98 130 14 9.29 sync 768 616 1.25 477 334 1.43 softdep 413 252 1.64 241 38 6.34 Second system normal 329 81 4.06 263.5 93.5 2.81 async 302 25.7 11.75 112 2.26 49.56 sync 281 57.0 4.93 263 90.5 2.9 softdep 341 40.6 8.4 284 4.76 59.66 "old dirpref" and "new dirpref" columns give a test time in seconds. speedup - speed increasement in times, ie. old dirpref / new dirpref. ------ Algorithm description The old dirpref algorithm is described in comments: /* * Find a cylinder to place a directory. * * The policy implemented by this algorithm is to select from * among those cylinder groups with above the average number of * free inodes, the one with the smallest number of directories. */ A new directory is allocated in a different cylinder groups than its parent directory resulting in a directory tree that is spreaded across all the cylinder groups. This spreading out results in a non-optimal access to the directories and files. When we have a small filesystem it is not a problem but when the filesystem is big then perfomance degradation becomes very apparent. What I mean by a big file system ? 1. A big filesystem is a filesystem which occupy 20-30 or more percent of total drive space, i.e. first and last cylinder are physically located relatively far from each other. 2. It has a relatively large number of cylinder groups, for example more cylinder groups than 50% of the buffers in the buffer cache. The first results in long access times, while the second results in many buffers being used by metadata operations. Such operations use cylinder group blocks and on-disk inode blocks. The cylinder group block (fs->fs_cblkno) contains struct cg, inode and block bit maps. It is 2k in size for the default filesystem parameters. If new and parent directories are located in different cylinder groups then the system performs more input/output operations and uses more buffers. On filesystems with many cylinder groups, lots of cache buffers are used for metadata operations. My solution for this problem is very simple. I allocate many directories in one cylinder group. I also do some things, so that the new allocation method does not cause excessive fragmentation and all directory inodes will not be located at a location far from its file's inodes and data. The algorithm is: /* * 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. */ My early versions of dirpref give me a good results for a wide range of file operations and different filesystem capacities except one case: those applications that create their entire directory structure first and only later fill this structure with files. My solution for such and similar cases is to limit a number of directories which may be created one after another in the same cylinder group without intervening file creations. For this purpose, I allocate an array of counters at mount time. This array is linked to the superblock fs->fs_contigdirs[cg]. Each time a directory is created the counter increases and each time a file is created the counter decreases. A 60Gb filesystem with 8mb/cg requires 10kb of memory for the counters array. The maxcontigdirs is a maximum number of directories which may be created without an intervening file creation. I found in my tests that the best performance occurs when I restrict the number of directories in one cylinder group such that all its files may be located in the same cylinder group. There may be some deterioration in performance if all the file inodes are in the same cylinder group as its containing directory, but their data partially resides in a different cylinder group. The maxcontigdirs value is calculated to try to prevent this condition. Since there is no way to know how many files and directories will be allocated later I added two optimization parameters in superblock/tunefs. They are: int32_t fs_avgfilesize; /* expected average file size */ int32_t fs_avgfpdir; /* expected # of files per directory */ These parameters have reasonable defaults but may be tweeked for special uses of a filesystem. They are only necessary in rare cases like better tuning a filesystem being used to store a squid cache. I have been using this algorithm for about 3 months. I have done a lot of testing on filesystems with different capacities, average filesize, average number of files per directory, and so on. I think this algorithm has no negative impact on filesystem perfomance. It works better than the default one in all cases. The new dirpref will greatly improve untarring/removing/coping of big directories, decrease load on cvs servers and much more. The new dirpref doesn't speedup a compilation process, but also doesn't slow it down. Obtained from: Grigoriy Orlov <gluk@ptci.ru>
2001-04-10 08:38:59 +00:00
warnx("%s remains unchanged as %d", name, fvalue);
}
else {
warnx("%s changes from %d to %d",
name, sblock.fs_avgfilesize, fvalue);
sblock.fs_avgfilesize = fvalue;
}
}
if (jflag) {
name = "soft updates journaling";
if (strcmp(jvalue, "enable") == 0) {
if ((sblock.fs_flags & (FS_DOSOFTDEP | FS_SUJ)) ==
(FS_DOSOFTDEP | FS_SUJ)) {
warnx("%s remains unchanged as enabled", name);
} else if (sblock.fs_clean == 0) {
warnx("%s cannot be enabled until fsck is run",
name);
} else if (journal_alloc(Svalue) != 0) {
warnx("%s can not be enabled", name);
} else {
sblock.fs_flags |= FS_DOSOFTDEP | FS_SUJ;
warnx("%s set", name);
}
} else if (strcmp(jvalue, "disable") == 0) {
if ((~sblock.fs_flags & FS_SUJ) == FS_SUJ) {
warnx("%s remains unchanged as disabled", name);
} else {
journal_clear();
sblock.fs_flags &= ~FS_SUJ;
sblock.fs_sujfree = 0;
warnx("%s cleared but soft updates still set.",
name);
warnx("remove .sujournal to reclaim space");
}
}
}
if (Jflag) {
name = "gjournal";
if (strcmp(Jvalue, "enable") == 0) {
if (sblock.fs_flags & FS_GJOURNAL) {
warnx("%s remains unchanged as enabled", name);
} else {
sblock.fs_flags |= FS_GJOURNAL;
warnx("%s set", name);
}
} else if (strcmp(Jvalue, "disable") == 0) {
if ((~sblock.fs_flags & FS_GJOURNAL) ==
FS_GJOURNAL) {
warnx("%s remains unchanged as disabled",
name);
} else {
sblock.fs_flags &= ~FS_GJOURNAL;
warnx("%s cleared", name);
}
}
}
if (kflag) {
name = "space to hold for metadata blocks";
if (sblock.fs_metaspace == kvalue)
warnx("%s remains unchanged as %d", name, kvalue);
else {
kvalue = blknum(&sblock, kvalue);
if (kvalue > sblock.fs_fpg / 2) {
kvalue = blknum(&sblock, sblock.fs_fpg / 2);
warnx("%s cannot exceed half the file system "
"space", name);
}
warnx("%s changes from %jd to %d",
name, sblock.fs_metaspace, kvalue);
sblock.fs_metaspace = kvalue;
}
}
if (lflag) {
name = "multilabel";
if (strcmp(lvalue, "enable") == 0) {
if (sblock.fs_flags & FS_MULTILABEL) {
warnx("%s remains unchanged as enabled", name);
} else {
sblock.fs_flags |= FS_MULTILABEL;
warnx("%s set", name);
}
} else if (strcmp(lvalue, "disable") == 0) {
if ((~sblock.fs_flags & FS_MULTILABEL) ==
FS_MULTILABEL) {
warnx("%s remains unchanged as disabled",
name);
} else {
sblock.fs_flags &= ~FS_MULTILABEL;
warnx("%s cleared", name);
}
}
}
if (mflag) {
name = "minimum percentage of free space";
if (sblock.fs_minfree == mvalue)
warnx("%s remains unchanged as %d%%", name, mvalue);
else {
warnx("%s changes from %d%% to %d%%",
name, sblock.fs_minfree, mvalue);
sblock.fs_minfree = mvalue;
if (mvalue >= MINFREE && sblock.fs_optim == FS_OPTSPACE)
warnx(OPTWARN, "time", ">=", MINFREE);
if (mvalue < MINFREE && sblock.fs_optim == FS_OPTTIME)
warnx(OPTWARN, "space", "<", MINFREE);
}
}
if (Nflag) {
name = "NFSv4 ACLs";
if (strcmp(Nvalue, "enable") == 0) {
if (sblock.fs_flags & FS_NFS4ACLS) {
warnx("%s remains unchanged as enabled", name);
} else if (sblock.fs_flags & FS_ACLS) {
warnx("%s and POSIX.1e ACLs are mutually "
"exclusive", name);
} else {
sblock.fs_flags |= FS_NFS4ACLS;
warnx("%s set", name);
}
} else if (strcmp(Nvalue, "disable") == 0) {
if ((~sblock.fs_flags & FS_NFS4ACLS) ==
FS_NFS4ACLS) {
warnx("%s remains unchanged as disabled",
name);
} else {
sblock.fs_flags &= ~FS_NFS4ACLS;
warnx("%s cleared", name);
}
}
}
if (nflag) {
name = "soft updates";
if (strcmp(nvalue, "enable") == 0) {
if (sblock.fs_flags & FS_DOSOFTDEP)
warnx("%s remains unchanged as enabled", name);
else if (sblock.fs_clean == 0) {
warnx("%s cannot be enabled until fsck is run",
name);
} else {
sblock.fs_flags |= FS_DOSOFTDEP;
warnx("%s set", name);
}
} else if (strcmp(nvalue, "disable") == 0) {
if ((~sblock.fs_flags & FS_DOSOFTDEP) == FS_DOSOFTDEP)
warnx("%s remains unchanged as disabled", name);
else {
sblock.fs_flags &= ~FS_DOSOFTDEP;
warnx("%s cleared", name);
}
}
}
if (oflag) {
name = "optimization preference";
chg[FS_OPTSPACE] = "space";
chg[FS_OPTTIME] = "time";
if (sblock.fs_optim == ovalue)
warnx("%s remains unchanged as %s", name, chg[ovalue]);
else {
warnx("%s changes from %s to %s",
name, chg[sblock.fs_optim], chg[ovalue]);
sblock.fs_optim = ovalue;
if (sblock.fs_minfree >= MINFREE &&
ovalue == FS_OPTSPACE)
warnx(OPTWARN, "time", ">=", MINFREE);
if (sblock.fs_minfree < MINFREE && ovalue == FS_OPTTIME)
warnx(OPTWARN, "space", "<", MINFREE);
}
}
Directory layout preference improvements from Grigoriy Orlov <gluk@ptci.ru>. His description of the problem and solution follow. My own tests show speedups on typical filesystem intensive workloads of 5% to 12% which is very impressive considering the small amount of code change involved. ------ One day I noticed that some file operations run much faster on small file systems then on big ones. I've looked at the ffs algorithms, thought about them, and redesigned the dirpref algorithm. First I want to describe the results of my tests. These results are old and I have improved the algorithm after these tests were done. Nevertheless they show how big the perfomance speedup may be. I have done two file/directory intensive tests on a two OpenBSD systems with old and new dirpref algorithm. The first test is "tar -xzf ports.tar.gz", the second is "rm -rf ports". The ports.tar.gz file is the ports collection from the OpenBSD 2.8 release. It contains 6596 directories and 13868 files. The test systems are: 1. Celeron-450, 128Mb, two IDE drives, the system at wd0, file system for test is at wd1. Size of test file system is 8 Gb, number of cg=991, size of cg is 8m, block size = 8k, fragment size = 1k OpenBSD-current from Dec 2000 with BUFCACHEPERCENT=35 2. PIII-600, 128Mb, two IBM DTLA-307045 IDE drives at i815e, the system at wd0, file system for test is at wd1. Size of test file system is 40 Gb, number of cg=5324, size of cg is 8m, block size = 8k, fragment size = 1k OpenBSD-current from Dec 2000 with BUFCACHEPERCENT=50 You can get more info about the test systems and methods at: http://www.ptci.ru/gluk/dirpref/old/dirpref.html Test Results tar -xzf ports.tar.gz rm -rf ports mode old dirpref new dirpref speedup old dirprefnew dirpref speedup First system normal 667 472 1.41 477 331 1.44 async 285 144 1.98 130 14 9.29 sync 768 616 1.25 477 334 1.43 softdep 413 252 1.64 241 38 6.34 Second system normal 329 81 4.06 263.5 93.5 2.81 async 302 25.7 11.75 112 2.26 49.56 sync 281 57.0 4.93 263 90.5 2.9 softdep 341 40.6 8.4 284 4.76 59.66 "old dirpref" and "new dirpref" columns give a test time in seconds. speedup - speed increasement in times, ie. old dirpref / new dirpref. ------ Algorithm description The old dirpref algorithm is described in comments: /* * Find a cylinder to place a directory. * * The policy implemented by this algorithm is to select from * among those cylinder groups with above the average number of * free inodes, the one with the smallest number of directories. */ A new directory is allocated in a different cylinder groups than its parent directory resulting in a directory tree that is spreaded across all the cylinder groups. This spreading out results in a non-optimal access to the directories and files. When we have a small filesystem it is not a problem but when the filesystem is big then perfomance degradation becomes very apparent. What I mean by a big file system ? 1. A big filesystem is a filesystem which occupy 20-30 or more percent of total drive space, i.e. first and last cylinder are physically located relatively far from each other. 2. It has a relatively large number of cylinder groups, for example more cylinder groups than 50% of the buffers in the buffer cache. The first results in long access times, while the second results in many buffers being used by metadata operations. Such operations use cylinder group blocks and on-disk inode blocks. The cylinder group block (fs->fs_cblkno) contains struct cg, inode and block bit maps. It is 2k in size for the default filesystem parameters. If new and parent directories are located in different cylinder groups then the system performs more input/output operations and uses more buffers. On filesystems with many cylinder groups, lots of cache buffers are used for metadata operations. My solution for this problem is very simple. I allocate many directories in one cylinder group. I also do some things, so that the new allocation method does not cause excessive fragmentation and all directory inodes will not be located at a location far from its file's inodes and data. The algorithm is: /* * 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. */ My early versions of dirpref give me a good results for a wide range of file operations and different filesystem capacities except one case: those applications that create their entire directory structure first and only later fill this structure with files. My solution for such and similar cases is to limit a number of directories which may be created one after another in the same cylinder group without intervening file creations. For this purpose, I allocate an array of counters at mount time. This array is linked to the superblock fs->fs_contigdirs[cg]. Each time a directory is created the counter increases and each time a file is created the counter decreases. A 60Gb filesystem with 8mb/cg requires 10kb of memory for the counters array. The maxcontigdirs is a maximum number of directories which may be created without an intervening file creation. I found in my tests that the best performance occurs when I restrict the number of directories in one cylinder group such that all its files may be located in the same cylinder group. There may be some deterioration in performance if all the file inodes are in the same cylinder group as its containing directory, but their data partially resides in a different cylinder group. The maxcontigdirs value is calculated to try to prevent this condition. Since there is no way to know how many files and directories will be allocated later I added two optimization parameters in superblock/tunefs. They are: int32_t fs_avgfilesize; /* expected average file size */ int32_t fs_avgfpdir; /* expected # of files per directory */ These parameters have reasonable defaults but may be tweeked for special uses of a filesystem. They are only necessary in rare cases like better tuning a filesystem being used to store a squid cache. I have been using this algorithm for about 3 months. I have done a lot of testing on filesystems with different capacities, average filesize, average number of files per directory, and so on. I think this algorithm has no negative impact on filesystem perfomance. It works better than the default one in all cases. The new dirpref will greatly improve untarring/removing/coping of big directories, decrease load on cvs servers and much more. The new dirpref doesn't speedup a compilation process, but also doesn't slow it down. Obtained from: Grigoriy Orlov <gluk@ptci.ru>
2001-04-10 08:38:59 +00:00
if (sflag) {
name = "expected number of files per directory";
2010-02-11 06:33:35 +00:00
if (sblock.fs_avgfpdir == (unsigned)svalue) {
Directory layout preference improvements from Grigoriy Orlov <gluk@ptci.ru>. His description of the problem and solution follow. My own tests show speedups on typical filesystem intensive workloads of 5% to 12% which is very impressive considering the small amount of code change involved. ------ One day I noticed that some file operations run much faster on small file systems then on big ones. I've looked at the ffs algorithms, thought about them, and redesigned the dirpref algorithm. First I want to describe the results of my tests. These results are old and I have improved the algorithm after these tests were done. Nevertheless they show how big the perfomance speedup may be. I have done two file/directory intensive tests on a two OpenBSD systems with old and new dirpref algorithm. The first test is "tar -xzf ports.tar.gz", the second is "rm -rf ports". The ports.tar.gz file is the ports collection from the OpenBSD 2.8 release. It contains 6596 directories and 13868 files. The test systems are: 1. Celeron-450, 128Mb, two IDE drives, the system at wd0, file system for test is at wd1. Size of test file system is 8 Gb, number of cg=991, size of cg is 8m, block size = 8k, fragment size = 1k OpenBSD-current from Dec 2000 with BUFCACHEPERCENT=35 2. PIII-600, 128Mb, two IBM DTLA-307045 IDE drives at i815e, the system at wd0, file system for test is at wd1. Size of test file system is 40 Gb, number of cg=5324, size of cg is 8m, block size = 8k, fragment size = 1k OpenBSD-current from Dec 2000 with BUFCACHEPERCENT=50 You can get more info about the test systems and methods at: http://www.ptci.ru/gluk/dirpref/old/dirpref.html Test Results tar -xzf ports.tar.gz rm -rf ports mode old dirpref new dirpref speedup old dirprefnew dirpref speedup First system normal 667 472 1.41 477 331 1.44 async 285 144 1.98 130 14 9.29 sync 768 616 1.25 477 334 1.43 softdep 413 252 1.64 241 38 6.34 Second system normal 329 81 4.06 263.5 93.5 2.81 async 302 25.7 11.75 112 2.26 49.56 sync 281 57.0 4.93 263 90.5 2.9 softdep 341 40.6 8.4 284 4.76 59.66 "old dirpref" and "new dirpref" columns give a test time in seconds. speedup - speed increasement in times, ie. old dirpref / new dirpref. ------ Algorithm description The old dirpref algorithm is described in comments: /* * Find a cylinder to place a directory. * * The policy implemented by this algorithm is to select from * among those cylinder groups with above the average number of * free inodes, the one with the smallest number of directories. */ A new directory is allocated in a different cylinder groups than its parent directory resulting in a directory tree that is spreaded across all the cylinder groups. This spreading out results in a non-optimal access to the directories and files. When we have a small filesystem it is not a problem but when the filesystem is big then perfomance degradation becomes very apparent. What I mean by a big file system ? 1. A big filesystem is a filesystem which occupy 20-30 or more percent of total drive space, i.e. first and last cylinder are physically located relatively far from each other. 2. It has a relatively large number of cylinder groups, for example more cylinder groups than 50% of the buffers in the buffer cache. The first results in long access times, while the second results in many buffers being used by metadata operations. Such operations use cylinder group blocks and on-disk inode blocks. The cylinder group block (fs->fs_cblkno) contains struct cg, inode and block bit maps. It is 2k in size for the default filesystem parameters. If new and parent directories are located in different cylinder groups then the system performs more input/output operations and uses more buffers. On filesystems with many cylinder groups, lots of cache buffers are used for metadata operations. My solution for this problem is very simple. I allocate many directories in one cylinder group. I also do some things, so that the new allocation method does not cause excessive fragmentation and all directory inodes will not be located at a location far from its file's inodes and data. The algorithm is: /* * 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. */ My early versions of dirpref give me a good results for a wide range of file operations and different filesystem capacities except one case: those applications that create their entire directory structure first and only later fill this structure with files. My solution for such and similar cases is to limit a number of directories which may be created one after another in the same cylinder group without intervening file creations. For this purpose, I allocate an array of counters at mount time. This array is linked to the superblock fs->fs_contigdirs[cg]. Each time a directory is created the counter increases and each time a file is created the counter decreases. A 60Gb filesystem with 8mb/cg requires 10kb of memory for the counters array. The maxcontigdirs is a maximum number of directories which may be created without an intervening file creation. I found in my tests that the best performance occurs when I restrict the number of directories in one cylinder group such that all its files may be located in the same cylinder group. There may be some deterioration in performance if all the file inodes are in the same cylinder group as its containing directory, but their data partially resides in a different cylinder group. The maxcontigdirs value is calculated to try to prevent this condition. Since there is no way to know how many files and directories will be allocated later I added two optimization parameters in superblock/tunefs. They are: int32_t fs_avgfilesize; /* expected average file size */ int32_t fs_avgfpdir; /* expected # of files per directory */ These parameters have reasonable defaults but may be tweeked for special uses of a filesystem. They are only necessary in rare cases like better tuning a filesystem being used to store a squid cache. I have been using this algorithm for about 3 months. I have done a lot of testing on filesystems with different capacities, average filesize, average number of files per directory, and so on. I think this algorithm has no negative impact on filesystem perfomance. It works better than the default one in all cases. The new dirpref will greatly improve untarring/removing/coping of big directories, decrease load on cvs servers and much more. The new dirpref doesn't speedup a compilation process, but also doesn't slow it down. Obtained from: Grigoriy Orlov <gluk@ptci.ru>
2001-04-10 08:38:59 +00:00
warnx("%s remains unchanged as %d", name, svalue);
}
else {
warnx("%s changes from %d to %d",
name, sblock.fs_avgfpdir, svalue);
sblock.fs_avgfpdir = svalue;
}
}
if (tflag) {
name = "issue TRIM to the disk";
if (strcmp(tvalue, "enable") == 0) {
if (sblock.fs_flags & FS_TRIM)
warnx("%s remains unchanged as enabled", name);
else {
sblock.fs_flags |= FS_TRIM;
warnx("%s set", name);
}
} else if (strcmp(tvalue, "disable") == 0) {
if ((~sblock.fs_flags & FS_TRIM) == FS_TRIM)
warnx("%s remains unchanged as disabled", name);
else {
sblock.fs_flags &= ~FS_TRIM;
warnx("%s cleared", name);
}
}
}
if (sbwrite(&disk, Aflag) == -1)
goto err;
ufs_disk_close(&disk);
if (active) {
build_iovec_argf(&iov, &iovlen, "fstype", "ufs");
build_iovec_argf(&iov, &iovlen, "fspath", "%s", on);
build_iovec(&iov, &iovlen, "errmsg", errmsg, sizeof(errmsg));
if (nmount(iov, iovlen,
stfs.f_flags | MNT_UPDATE | MNT_RELOAD) < 0) {
if (errmsg[0])
err(9, "%s: reload: %s", special, errmsg);
else
err(9, "%s: reload", special);
}
warnx("file system reloaded");
}
exit(0);
err:
if (disk.d_error != NULL)
errx(11, "%s: %s", special, disk.d_error);
else
err(12, "%s", special);
}
static void
sbdirty(void)
{
disk.d_fs.fs_flags |= FS_UNCLEAN | FS_NEEDSFSCK;
disk.d_fs.fs_clean = 0;
}
static ufs2_daddr_t
journal_balloc(void)
{
ufs2_daddr_t blk;
struct cg *cgp;
int valid;
static int contig = 1;
cgp = &disk.d_cg;
for (;;) {
blk = cgballoc(&disk);
if (blk > 0)
break;
/*
* If we failed to allocate a block from this cg, move to
* the next.
*/
if (cgwrite(&disk) < 0) {
warn("Failed to write updated cg");
return (-1);
}
while ((valid = cgread(&disk)) == 1) {
/*
* Try to minimize fragmentation by requiring a minimum
* number of blocks present.
*/
if (cgp->cg_cs.cs_nbfree > 256 * 1024)
break;
if (contig == 0 && cgp->cg_cs.cs_nbfree)
break;
}
if (valid)
continue;
/*
* Try once through looking only for large contiguous regions
* and again taking any space we can find.
*/
if (contig) {
contig = 0;
disk.d_ccg = 0;
warnx("Journal file fragmented.");
continue;
}
warnx("Failed to find sufficient free blocks for the journal");
return -1;
}
if (bwrite(&disk, fsbtodb(&sblock, blk), clrbuf,
sblock.fs_bsize) <= 0) {
warn("Failed to initialize new block");
return -1;
}
return (blk);
}
/*
* Search a directory block for the SUJ_FILE.
*/
static ino_t
dir_search(ufs2_daddr_t blk, int bytes)
{
char block[MAXBSIZE];
struct direct *dp;
int off;
if (bread(&disk, fsbtodb(&sblock, blk), block, bytes) <= 0) {
warn("Failed to read dir block");
return (-1);
}
for (off = 0; off < bytes; off += dp->d_reclen) {
dp = (struct direct *)&block[off];
if (dp->d_reclen == 0)
break;
if (dp->d_ino == 0)
continue;
if (dp->d_namlen != strlen(SUJ_FILE))
continue;
if (bcmp(dp->d_name, SUJ_FILE, dp->d_namlen) != 0)
continue;
return (dp->d_ino);
}
return (0);
}
/*
* Search in the UFS_ROOTINO for the SUJ_FILE. If it exists we can not enable
* journaling.
*/
static ino_t
journal_findfile(void)
{
struct ufs1_dinode *dp1;
struct ufs2_dinode *dp2;
ino_t ino;
int mode;
void *ip;
int i;
if (getino(&disk, &ip, UFS_ROOTINO, &mode) != 0) {
warn("Failed to get root inode");
return (-1);
}
dp2 = ip;
dp1 = ip;
if (sblock.fs_magic == FS_UFS1_MAGIC) {
if ((off_t)dp1->di_size >= lblktosize(&sblock, UFS_NDADDR)) {
warnx("UFS_ROOTINO extends beyond direct blocks.");
return (-1);
}
for (i = 0; i < UFS_NDADDR; i++) {
if (dp1->di_db[i] == 0)
break;
if ((ino = dir_search(dp1->di_db[i],
sblksize(&sblock, (off_t)dp1->di_size, i))) != 0)
return (ino);
}
} else {
if ((off_t)dp2->di_size >= lblktosize(&sblock, UFS_NDADDR)) {
warnx("UFS_ROOTINO extends beyond direct blocks.");
return (-1);
}
for (i = 0; i < UFS_NDADDR; i++) {
if (dp2->di_db[i] == 0)
break;
if ((ino = dir_search(dp2->di_db[i],
sblksize(&sblock, (off_t)dp2->di_size, i))) != 0)
return (ino);
}
}
return (0);
}
static void
dir_clear_block(const char *block, off_t off)
{
struct direct *dp;
for (; off < sblock.fs_bsize; off += DIRBLKSIZ) {
dp = (struct direct *)&block[off];
dp->d_ino = 0;
dp->d_reclen = DIRBLKSIZ;
dp->d_type = DT_UNKNOWN;
}
}
/*
* Insert the journal at inode 'ino' into directory blk 'blk' at the first
* free offset of 'off'. DIRBLKSIZ blocks after off are initialized as
* empty.
*/
static int
dir_insert(ufs2_daddr_t blk, off_t off, ino_t ino)
{
struct direct *dp;
char block[MAXBSIZE];
if (bread(&disk, fsbtodb(&sblock, blk), block, sblock.fs_bsize) <= 0) {
warn("Failed to read dir block");
return (-1);
}
bzero(&block[off], sblock.fs_bsize - off);
dp = (struct direct *)&block[off];
dp->d_ino = ino;
dp->d_reclen = DIRBLKSIZ;
dp->d_type = DT_REG;
dp->d_namlen = strlen(SUJ_FILE);
bcopy(SUJ_FILE, &dp->d_name, strlen(SUJ_FILE));
dir_clear_block(block, off + DIRBLKSIZ);
if (bwrite(&disk, fsbtodb(&sblock, blk), block, sblock.fs_bsize) <= 0) {
warn("Failed to write dir block");
return (-1);
}
return (0);
}
/*
* Extend a directory block in 'blk' by copying it to a full size block
* and inserting the new journal inode into .sujournal.
*/
static int
dir_extend(ufs2_daddr_t blk, ufs2_daddr_t nblk, off_t size, ino_t ino)
{
char block[MAXBSIZE];
if (bread(&disk, fsbtodb(&sblock, blk), block,
roundup(size, sblock.fs_fsize)) <= 0) {
warn("Failed to read dir block");
return (-1);
}
dir_clear_block(block, size);
if (bwrite(&disk, fsbtodb(&sblock, nblk), block, sblock.fs_bsize)
<= 0) {
warn("Failed to write dir block");
return (-1);
}
return (dir_insert(nblk, size, ino));
}
/*
* Insert the journal file into the UFS_ROOTINO directory. We always extend the
* last frag
*/
static int
journal_insertfile(ino_t ino)
{
struct ufs1_dinode *dp1;
struct ufs2_dinode *dp2;
void *ip;
ufs2_daddr_t nblk;
ufs2_daddr_t blk;
ufs_lbn_t lbn;
int size;
int mode;
int off;
if (getino(&disk, &ip, UFS_ROOTINO, &mode) != 0) {
warn("Failed to get root inode");
sbdirty();
return (-1);
}
dp2 = ip;
dp1 = ip;
blk = 0;
size = 0;
nblk = journal_balloc();
if (nblk <= 0)
return (-1);
/*
* For simplicity sake we aways extend the UFS_ROOTINO into a new
* directory block rather than searching for space and inserting
* into an existing block. However, if the rootino has frags
* have to free them and extend the block.
*/
if (sblock.fs_magic == FS_UFS1_MAGIC) {
lbn = lblkno(&sblock, dp1->di_size);
off = blkoff(&sblock, dp1->di_size);
blk = dp1->di_db[lbn];
size = sblksize(&sblock, (off_t)dp1->di_size, lbn);
} else {
lbn = lblkno(&sblock, dp2->di_size);
off = blkoff(&sblock, dp2->di_size);
blk = dp2->di_db[lbn];
size = sblksize(&sblock, (off_t)dp2->di_size, lbn);
}
if (off != 0) {
if (dir_extend(blk, nblk, off, ino) == -1)
return (-1);
} else {
blk = 0;
if (dir_insert(nblk, 0, ino) == -1)
return (-1);
}
if (sblock.fs_magic == FS_UFS1_MAGIC) {
dp1->di_blocks += (sblock.fs_bsize - size) / DEV_BSIZE;
dp1->di_db[lbn] = nblk;
dp1->di_size = lblktosize(&sblock, lbn+1);
} else {
dp2->di_blocks += (sblock.fs_bsize - size) / DEV_BSIZE;
dp2->di_db[lbn] = nblk;
dp2->di_size = lblktosize(&sblock, lbn+1);
}
if (putino(&disk) < 0) {
warn("Failed to write root inode");
return (-1);
}
if (cgwrite(&disk) < 0) {
warn("Failed to write updated cg");
sbdirty();
return (-1);
}
if (blk) {
if (cgbfree(&disk, blk, size) < 0) {
warn("Failed to write cg");
return (-1);
}
}
return (0);
}
static int
indir_fill(ufs2_daddr_t blk, int level, int *resid)
{
char indirbuf[MAXBSIZE];
ufs1_daddr_t *bap1;
ufs2_daddr_t *bap2;
ufs2_daddr_t nblk;
int ncnt;
int cnt;
int i;
bzero(indirbuf, sizeof(indirbuf));
bap1 = (ufs1_daddr_t *)indirbuf;
bap2 = (void *)bap1;
cnt = 0;
for (i = 0; i < NINDIR(&sblock) && *resid != 0; i++) {
nblk = journal_balloc();
if (nblk <= 0)
return (-1);
cnt++;
if (sblock.fs_magic == FS_UFS1_MAGIC)
*bap1++ = nblk;
else
*bap2++ = nblk;
if (level != 0) {
ncnt = indir_fill(nblk, level - 1, resid);
if (ncnt <= 0)
return (-1);
cnt += ncnt;
} else
(*resid)--;
}
if (bwrite(&disk, fsbtodb(&sblock, blk), indirbuf,
sblock.fs_bsize) <= 0) {
warn("Failed to write indirect");
return (-1);
}
return (cnt);
}
/*
* Clear the flag bits so the journal can be removed.
*/
static void
journal_clear(void)
{
struct ufs1_dinode *dp1;
struct ufs2_dinode *dp2;
ino_t ino;
int mode;
void *ip;
ino = journal_findfile();
if (ino == (ino_t)-1 || ino == 0) {
warnx("Journal file does not exist");
return;
}
printf("Clearing journal flags from inode %ju\n", (uintmax_t)ino);
if (getino(&disk, &ip, ino, &mode) != 0) {
warn("Failed to get journal inode");
return;
}
dp2 = ip;
dp1 = ip;
if (sblock.fs_magic == FS_UFS1_MAGIC)
dp1->di_flags = 0;
else
dp2->di_flags = 0;
if (putino(&disk) < 0) {
warn("Failed to write journal inode");
return;
}
}
static int
journal_alloc(int64_t size)
{
struct ufs1_dinode *dp1;
struct ufs2_dinode *dp2;
ufs2_daddr_t blk;
void *ip;
struct cg *cgp;
int resid;
ino_t ino;
int blks;
int mode;
time_t utime;
int i;
cgp = &disk.d_cg;
ino = 0;
/*
* If the journal file exists we can't allocate it.
*/
ino = journal_findfile();
if (ino == (ino_t)-1)
return (-1);
if (ino > 0) {
warnx("Journal file %s already exists, please remove.",
SUJ_FILE);
return (-1);
}
/*
* If the user didn't supply a size pick one based on the filesystem
* size constrained with hardcoded MIN and MAX values. We opt for
* 1/1024th of the filesystem up to MAX but not exceeding one CG and
* not less than the MIN.
*/
if (size == 0) {
size = (sblock.fs_size * sblock.fs_bsize) / 1024;
size = MIN(SUJ_MAX, size);
if (size / sblock.fs_fsize > sblock.fs_fpg)
size = sblock.fs_fpg * sblock.fs_fsize;
size = MAX(SUJ_MIN, size);
/* fsck does not support fragments in journal files. */
size = roundup(size, sblock.fs_bsize);
}
resid = blocks = size / sblock.fs_bsize;
if (sblock.fs_cstotal.cs_nbfree < blocks) {
warn("Insufficient free space for %jd byte journal", size);
return (-1);
}
/*
* Find a cg with enough blocks to satisfy the journal
* size. Presently the journal does not span cgs.
*/
while (cgread(&disk) == 1) {
if (cgp->cg_cs.cs_nifree == 0)
continue;
ino = cgialloc(&disk);
if (ino <= 0)
break;
printf("Using inode %ju in cg %d for %jd byte journal\n",
(uintmax_t)ino, cgp->cg_cgx, size);
if (getino(&disk, &ip, ino, &mode) != 0) {
warn("Failed to get allocated inode");
sbdirty();
goto out;
}
/*
* We leave fields unrelated to the number of allocated
* blocks and size uninitialized. This causes legacy
* fsck implementations to clear the inode.
*/
dp2 = ip;
dp1 = ip;
time(&utime);
if (sblock.fs_magic == FS_UFS1_MAGIC) {
bzero(dp1, sizeof(*dp1));
dp1->di_size = size;
2018-03-17 12:59:55 +00:00
dp1->di_mode = IFREG | IREAD;
dp1->di_nlink = 1;
dp1->di_flags = SF_IMMUTABLE | SF_NOUNLINK | UF_NODUMP;
dp1->di_atime = utime;
dp1->di_mtime = utime;
dp1->di_ctime = utime;
} else {
bzero(dp2, sizeof(*dp2));
dp2->di_size = size;
2018-03-17 12:59:55 +00:00
dp2->di_mode = IFREG | IREAD;
dp2->di_nlink = 1;
dp2->di_flags = SF_IMMUTABLE | SF_NOUNLINK | UF_NODUMP;
dp2->di_atime = utime;
dp2->di_mtime = utime;
dp2->di_ctime = utime;
dp2->di_birthtime = utime;
}
for (i = 0; i < UFS_NDADDR && resid; i++, resid--) {
blk = journal_balloc();
if (blk <= 0)
goto out;
if (sblock.fs_magic == FS_UFS1_MAGIC) {
dp1->di_db[i] = blk;
dp1->di_blocks++;
} else {
dp2->di_db[i] = blk;
dp2->di_blocks++;
}
}
for (i = 0; i < UFS_NIADDR && resid; i++) {
blk = journal_balloc();
if (blk <= 0)
goto out;
blks = indir_fill(blk, i, &resid) + 1;
if (blks <= 0) {
sbdirty();
goto out;
}
if (sblock.fs_magic == FS_UFS1_MAGIC) {
dp1->di_ib[i] = blk;
dp1->di_blocks += blks;
} else {
dp2->di_ib[i] = blk;
dp2->di_blocks += blks;
}
}
if (sblock.fs_magic == FS_UFS1_MAGIC)
dp1->di_blocks *= sblock.fs_bsize / disk.d_bsize;
else
dp2->di_blocks *= sblock.fs_bsize / disk.d_bsize;
if (putino(&disk) < 0) {
warn("Failed to write inode");
sbdirty();
return (-1);
}
if (cgwrite(&disk) < 0) {
warn("Failed to write updated cg");
sbdirty();
return (-1);
}
if (journal_insertfile(ino) < 0) {
sbdirty();
return (-1);
}
sblock.fs_sujfree = 0;
return (0);
}
warnx("Insufficient free space for the journal.");
out:
return (-1);
}
static void
usage(void)
{
fprintf(stderr, "%s\n%s\n%s\n%s\n%s\n%s\n",
2003-02-23 01:50:07 +00:00
"usage: tunefs [-A] [-a enable | disable] [-e maxbpg] [-f avgfilesize]",
" [-J enable | disable] [-j enable | disable] [-k metaspace]",
" [-L volname] [-l enable | disable] [-m minfree]",
" [-N enable | disable] [-n enable | disable]",
" [-o space | time] [-p] [-s avgfpdir] [-t enable | disable]",
" special | filesystem");
exit(2);
}
static void
printfs(void)
{
warnx("POSIX.1e ACLs: (-a) %s",
(sblock.fs_flags & FS_ACLS)? "enabled" : "disabled");
warnx("NFSv4 ACLs: (-N) %s",
(sblock.fs_flags & FS_NFS4ACLS)? "enabled" : "disabled");
warnx("MAC multilabel: (-l) %s",
(sblock.fs_flags & FS_MULTILABEL)? "enabled" : "disabled");
2003-01-18 06:29:15 +00:00
warnx("soft updates: (-n) %s",
(sblock.fs_flags & FS_DOSOFTDEP)? "enabled" : "disabled");
warnx("soft update journaling: (-j) %s",
(sblock.fs_flags & FS_SUJ)? "enabled" : "disabled");
warnx("gjournal: (-J) %s",
(sblock.fs_flags & FS_GJOURNAL)? "enabled" : "disabled");
warnx("trim: (-t) %s",
(sblock.fs_flags & FS_TRIM)? "enabled" : "disabled");
warnx("maximum blocks per file in a cylinder group: (-e) %d",
sblock.fs_maxbpg);
Directory layout preference improvements from Grigoriy Orlov <gluk@ptci.ru>. His description of the problem and solution follow. My own tests show speedups on typical filesystem intensive workloads of 5% to 12% which is very impressive considering the small amount of code change involved. ------ One day I noticed that some file operations run much faster on small file systems then on big ones. I've looked at the ffs algorithms, thought about them, and redesigned the dirpref algorithm. First I want to describe the results of my tests. These results are old and I have improved the algorithm after these tests were done. Nevertheless they show how big the perfomance speedup may be. I have done two file/directory intensive tests on a two OpenBSD systems with old and new dirpref algorithm. The first test is "tar -xzf ports.tar.gz", the second is "rm -rf ports". The ports.tar.gz file is the ports collection from the OpenBSD 2.8 release. It contains 6596 directories and 13868 files. The test systems are: 1. Celeron-450, 128Mb, two IDE drives, the system at wd0, file system for test is at wd1. Size of test file system is 8 Gb, number of cg=991, size of cg is 8m, block size = 8k, fragment size = 1k OpenBSD-current from Dec 2000 with BUFCACHEPERCENT=35 2. PIII-600, 128Mb, two IBM DTLA-307045 IDE drives at i815e, the system at wd0, file system for test is at wd1. Size of test file system is 40 Gb, number of cg=5324, size of cg is 8m, block size = 8k, fragment size = 1k OpenBSD-current from Dec 2000 with BUFCACHEPERCENT=50 You can get more info about the test systems and methods at: http://www.ptci.ru/gluk/dirpref/old/dirpref.html Test Results tar -xzf ports.tar.gz rm -rf ports mode old dirpref new dirpref speedup old dirprefnew dirpref speedup First system normal 667 472 1.41 477 331 1.44 async 285 144 1.98 130 14 9.29 sync 768 616 1.25 477 334 1.43 softdep 413 252 1.64 241 38 6.34 Second system normal 329 81 4.06 263.5 93.5 2.81 async 302 25.7 11.75 112 2.26 49.56 sync 281 57.0 4.93 263 90.5 2.9 softdep 341 40.6 8.4 284 4.76 59.66 "old dirpref" and "new dirpref" columns give a test time in seconds. speedup - speed increasement in times, ie. old dirpref / new dirpref. ------ Algorithm description The old dirpref algorithm is described in comments: /* * Find a cylinder to place a directory. * * The policy implemented by this algorithm is to select from * among those cylinder groups with above the average number of * free inodes, the one with the smallest number of directories. */ A new directory is allocated in a different cylinder groups than its parent directory resulting in a directory tree that is spreaded across all the cylinder groups. This spreading out results in a non-optimal access to the directories and files. When we have a small filesystem it is not a problem but when the filesystem is big then perfomance degradation becomes very apparent. What I mean by a big file system ? 1. A big filesystem is a filesystem which occupy 20-30 or more percent of total drive space, i.e. first and last cylinder are physically located relatively far from each other. 2. It has a relatively large number of cylinder groups, for example more cylinder groups than 50% of the buffers in the buffer cache. The first results in long access times, while the second results in many buffers being used by metadata operations. Such operations use cylinder group blocks and on-disk inode blocks. The cylinder group block (fs->fs_cblkno) contains struct cg, inode and block bit maps. It is 2k in size for the default filesystem parameters. If new and parent directories are located in different cylinder groups then the system performs more input/output operations and uses more buffers. On filesystems with many cylinder groups, lots of cache buffers are used for metadata operations. My solution for this problem is very simple. I allocate many directories in one cylinder group. I also do some things, so that the new allocation method does not cause excessive fragmentation and all directory inodes will not be located at a location far from its file's inodes and data. The algorithm is: /* * 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. */ My early versions of dirpref give me a good results for a wide range of file operations and different filesystem capacities except one case: those applications that create their entire directory structure first and only later fill this structure with files. My solution for such and similar cases is to limit a number of directories which may be created one after another in the same cylinder group without intervening file creations. For this purpose, I allocate an array of counters at mount time. This array is linked to the superblock fs->fs_contigdirs[cg]. Each time a directory is created the counter increases and each time a file is created the counter decreases. A 60Gb filesystem with 8mb/cg requires 10kb of memory for the counters array. The maxcontigdirs is a maximum number of directories which may be created without an intervening file creation. I found in my tests that the best performance occurs when I restrict the number of directories in one cylinder group such that all its files may be located in the same cylinder group. There may be some deterioration in performance if all the file inodes are in the same cylinder group as its containing directory, but their data partially resides in a different cylinder group. The maxcontigdirs value is calculated to try to prevent this condition. Since there is no way to know how many files and directories will be allocated later I added two optimization parameters in superblock/tunefs. They are: int32_t fs_avgfilesize; /* expected average file size */ int32_t fs_avgfpdir; /* expected # of files per directory */ These parameters have reasonable defaults but may be tweeked for special uses of a filesystem. They are only necessary in rare cases like better tuning a filesystem being used to store a squid cache. I have been using this algorithm for about 3 months. I have done a lot of testing on filesystems with different capacities, average filesize, average number of files per directory, and so on. I think this algorithm has no negative impact on filesystem perfomance. It works better than the default one in all cases. The new dirpref will greatly improve untarring/removing/coping of big directories, decrease load on cvs servers and much more. The new dirpref doesn't speedup a compilation process, but also doesn't slow it down. Obtained from: Grigoriy Orlov <gluk@ptci.ru>
2001-04-10 08:38:59 +00:00
warnx("average file size: (-f) %d",
sblock.fs_avgfilesize);
warnx("average number of files in a directory: (-s) %d",
sblock.fs_avgfpdir);
warnx("minimum percentage of free space: (-m) %d%%",
sblock.fs_minfree);
warnx("space to hold for metadata blocks: (-k) %jd",
sblock.fs_metaspace);
warnx("optimization preference: (-o) %s",
sblock.fs_optim == FS_OPTSPACE ? "space" : "time");
if (sblock.fs_minfree >= MINFREE &&
sblock.fs_optim == FS_OPTSPACE)
warnx(OPTWARN, "time", ">=", MINFREE);
if (sblock.fs_minfree < MINFREE &&
sblock.fs_optim == FS_OPTTIME)
warnx(OPTWARN, "space", "<", MINFREE);
warnx("volume label: (-L) %s",
sblock.fs_volname);
}