freebsd-skq/libexec/lfs_cleanerd/library.c
Justin T. Gibbs b77430dcb0 Remove -DDIAGNOSTIC in makefile. The DIAGNOSTIC code is severly broken and
will change if I have more time to look at it.  Keep at least 5 segments
cleaned if possible (instead of 2 which is a bare minimum for FS operation).
1995-01-04 23:54:06 +00:00

672 lines
17 KiB
C

/*-
* Copyright (c) 1992, 1993
* The Regents of the University of California. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the University of
* California, Berkeley and its contributors.
* 4. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#ifndef lint
static char sccsid[] = "@(#)library.c 8.1 (Berkeley) 6/4/93";
#endif /* not lint */
#include <sys/param.h>
#include <sys/time.h>
#include <sys/stat.h>
#include <sys/mount.h>
#include <sys/types.h>
#include <sys/mman.h>
#include <ufs/ufs/dinode.h>
#include <ufs/lfs/lfs.h>
#include <fcntl.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include "clean.h"
void add_blocks __P((FS_INFO *, BLOCK_INFO *, int *, SEGSUM *, caddr_t,
daddr_t, daddr_t));
void add_inodes __P((FS_INFO *, BLOCK_INFO *, int *, SEGSUM *, caddr_t,
daddr_t));
int bi_compare __P((const void *, const void *));
int bi_toss __P((const void *, const void *, const void *));
void get_ifile __P((FS_INFO *, int));
int get_superblock __P((FS_INFO *, struct lfs *));
int pseg_valid __P((FS_INFO *, SEGSUM *));
/*
* This function will get information on a a filesystem which matches
* the name and type given. If a "name" is in a filesystem of the given
* type, then buf is filled with that filesystem's info, and the
* a non-zero value is returned.
*/
int
fs_getmntinfo(buf, name, type)
struct statfs **buf;
char *name;
int type;
{
/* allocate space for the filesystem info */
*buf = (struct statfs *)malloc(sizeof(struct statfs));
if (*buf == NULL)
return 0;
/* grab the filesystem info */
if (statfs(name, *buf) < 0) {
free(*buf);
return 0;
}
/* check to see if it's the one we want */
if (((*buf)->f_type != type) ||
strncmp(name, (*buf)->f_mntonname, MNAMELEN)) {
/* "this is not the filesystem you're looking for" */
free(*buf);
return 0;
}
return 1;
}
/*
* Get all the information available on an LFS file system.
* Returns an pointer to an FS_INFO structure, NULL on error.
*/
FS_INFO *
get_fs_info (lstatfsp, use_mmap)
struct statfs *lstatfsp; /* IN: pointer to statfs struct */
int use_mmap; /* IN: mmap or read */
{
FS_INFO *fsp;
int i;
fsp = (FS_INFO *)malloc(sizeof(FS_INFO));
if (fsp == NULL)
return NULL;
bzero(fsp, sizeof(FS_INFO));
fsp->fi_statfsp = lstatfsp;
if (get_superblock (fsp, &fsp->fi_lfs))
err(1, "get_fs_info: get_superblock failed");
fsp->fi_daddr_shift =
fsp->fi_lfs.lfs_bshift - fsp->fi_lfs.lfs_fsbtodb;
get_ifile (fsp, use_mmap);
return (fsp);
}
/*
* If we are reading the ifile then we need to refresh it. Even if
* we are mmapping it, it might have grown. Finally, we need to
* refresh the file system information (statfs) info.
*/
void
reread_fs_info(fsp, use_mmap)
FS_INFO *fsp; /* IN: prointer fs_infos to reread */
int use_mmap;
{
int i;
if (statfs(fsp->fi_statfsp->f_mntonname, fsp->fi_statfsp))
err(1, "reread_fs_info: statfs failed");
get_ifile (fsp, use_mmap);
}
/*
* Gets the superblock from disk (possibly in face of errors)
*/
int
get_superblock (fsp, sbp)
FS_INFO *fsp; /* local file system info structure */
struct lfs *sbp;
{
char mntfromname[MNAMELEN+1];
int fid;
strcpy(mntfromname, "/dev/r");
strcat(mntfromname, fsp->fi_statfsp->f_mntfromname+5);
if ((fid = open(mntfromname, O_RDONLY, (mode_t)0)) < 0) {
err(0, "get_superblock: bad open");
return (-1);
}
get(fid, LFS_LABELPAD, sbp, sizeof(struct lfs));
close (fid);
return (0);
}
/*
* This function will map the ifile into memory. It causes a
* fatal error on failure.
*/
void
get_ifile (fsp, use_mmap)
FS_INFO *fsp;
int use_mmap;
{
struct stat file_stat;
caddr_t ifp;
char *ifile_name;
int count, fid;
ifp = NULL;
ifile_name = malloc(strlen(fsp->fi_statfsp->f_mntonname) +
strlen(IFILE_NAME)+2);
strcat(strcat(strcpy(ifile_name, fsp->fi_statfsp->f_mntonname), "/"),
IFILE_NAME);
if ((fid = open(ifile_name, O_RDWR, (mode_t)0)) < 0)
err(1, "get_ifile: bad open");
if (fstat (fid, &file_stat))
err(1, "get_ifile: fstat failed");
if (use_mmap && file_stat.st_size == fsp->fi_ifile_length) {
(void) close(fid);
return;
}
/* get the ifile */
if (use_mmap) {
if (fsp->fi_cip)
munmap((caddr_t)fsp->fi_cip, fsp->fi_ifile_length);
ifp = mmap ((caddr_t)0, file_stat.st_size,
PROT_READ|PROT_WRITE, 0, fid, (off_t)0);
if (ifp == (caddr_t)(-1))
err(1, "get_ifile: mmap failed");
} else {
if (fsp->fi_cip)
free(fsp->fi_cip);
if (!(ifp = malloc (file_stat.st_size)))
err (1, "get_ifile: malloc failed");
redo_read:
count = read (fid, ifp, (size_t) file_stat.st_size);
if (count < 0)
err(1, "get_ifile: bad ifile read");
else if (count < file_stat.st_size) {
err(0, "get_ifile");
if (lseek(fid, 0, SEEK_SET) < 0)
err(1, "get_ifile: bad ifile lseek");
goto redo_read;
}
}
fsp->fi_ifile_length = file_stat.st_size;
close (fid);
fsp->fi_cip = (CLEANERINFO *)ifp;
fsp->fi_segusep = (SEGUSE *)(ifp + CLEANSIZE(fsp));
fsp->fi_ifilep = (IFILE *)((caddr_t)fsp->fi_segusep + SEGTABSIZE(fsp));
/*
* The number of ifile entries is equal to the number of blocks
* blocks in the ifile minus the ones allocated to cleaner info
* and segment usage table multiplied by the number of ifile
* entries per page.
*/
fsp->fi_ifile_count = (fsp->fi_ifile_length >> fsp->fi_lfs.lfs_bshift -
fsp->fi_lfs.lfs_cleansz - fsp->fi_lfs.lfs_segtabsz) *
fsp->fi_lfs.lfs_ifpb;
free (ifile_name);
}
/*
* This function will scan a segment and return a list of
* <inode, blocknum> pairs which indicate which blocks were
* contained as live data within the segment when the segment
* summary was read (it may have "died" since then). Any given
* pair will be listed at most once.
*/
int
lfs_segmapv(fsp, seg, seg_buf, blocks, bcount)
FS_INFO *fsp; /* pointer to local file system information */
int seg; /* the segment number */
caddr_t seg_buf; /* the buffer containing the segment's data */
BLOCK_INFO **blocks; /* OUT: array of block_info for live blocks */
int *bcount; /* OUT: number of active blocks in segment */
{
BLOCK_INFO *bip;
SEGSUM *sp;
SEGUSE *sup;
FINFO *fip;
struct lfs *lfsp;
caddr_t s, segend;
daddr_t pseg_addr, seg_addr;
int i, nelem, nblocks, sumsize;
time_t timestamp;
lfsp = &fsp->fi_lfs;
nelem = 2 * lfsp->lfs_ssize;
if (!(bip = malloc(nelem * sizeof(BLOCK_INFO))))
goto err0;
sup = SEGUSE_ENTRY(lfsp, fsp->fi_segusep, seg);
s = seg_buf + (sup->su_flags & SEGUSE_SUPERBLOCK ? LFS_SBPAD : 0);
seg_addr = sntoda(lfsp, seg);
pseg_addr = seg_addr + (sup->su_flags & SEGUSE_SUPERBLOCK ? btodb(LFS_SBPAD) : 0);
#ifdef VERBOSE
printf("\tsegment buffer at: 0x%x\tseg_addr 0x%x\n", s, seg_addr);
#endif /* VERBOSE */
*bcount = 0;
for (segend = seg_buf + seg_size(lfsp), timestamp = 0; s < segend; ) {
sp = (SEGSUM *)s;
#ifdef VERBOSE
printf("\tpartial at: 0x%x\n", pseg_addr);
print_SEGSUM(lfsp, sp);
fflush(stdout);
#endif /* VERBOSE */
nblocks = pseg_valid(fsp, sp);
if (nblocks <= 0)
break;
/* Check if we have hit old data */
if (timestamp > ((SEGSUM*)s)->ss_create)
break;
timestamp = ((SEGSUM*)s)->ss_create;
#ifdef DIAGNOSTIC
/* Verify size of summary block */
sumsize = sizeof(SEGSUM) +
(sp->ss_ninos + INOPB(lfsp) - 1) / INOPB(lfsp);
for (fip = (FINFO *)(sp + 1); i < sp->ss_nfinfo; ++i) {
sumsize += sizeof(FINFO) +
(fip->fi_nblocks - 1) * sizeof(daddr_t);
fip = (FINFO *)(&fip->fi_blocks[fip->fi_nblocks]);
}
if (sumsize > LFS_SUMMARY_SIZE) {
fprintf(stderr,
"Segment %d summary block too big: %d\n",
seg, sumsize);
exit(1);
}
#endif
if (*bcount + nblocks + sp->ss_ninos > nelem) {
nelem = *bcount + nblocks + sp->ss_ninos;
bip = realloc (bip, nelem * sizeof(BLOCK_INFO));
if (!bip)
goto err0;
}
add_blocks(fsp, bip, bcount, sp, seg_buf, seg_addr, pseg_addr);
add_inodes(fsp, bip, bcount, sp, seg_buf, seg_addr);
pseg_addr += fsbtodb(lfsp, nblocks) +
bytetoda(fsp, LFS_SUMMARY_SIZE);
s += (nblocks << lfsp->lfs_bshift) + LFS_SUMMARY_SIZE;
}
qsort(bip, *bcount, sizeof(BLOCK_INFO), bi_compare);
toss(bip, bcount, sizeof(BLOCK_INFO), bi_toss, NULL);
#ifdef VERBOSE
{
BLOCK_INFO *_bip;
int i;
printf("BLOCK INFOS\n");
for (_bip = bip, i=0; i < *bcount; ++_bip, ++i)
PRINT_BINFO(_bip);
}
#endif
*blocks = bip;
return (0);
err0: *bcount = 0;
return (-1);
}
/*
* This will parse a partial segment and fill in BLOCK_INFO structures
* for each block described in the segment summary. It will not include
* blocks or inodes from files with new version numbers.
*/
void
add_blocks (fsp, bip, countp, sp, seg_buf, segaddr, psegaddr)
FS_INFO *fsp; /* pointer to super block */
BLOCK_INFO *bip; /* Block info array */
int *countp; /* IN/OUT: number of blocks in array */
SEGSUM *sp; /* segment summmary pointer */
caddr_t seg_buf; /* buffer containing segment */
daddr_t segaddr; /* address of this segment */
daddr_t psegaddr; /* address of this partial segment */
{
IFILE *ifp;
FINFO *fip;
caddr_t bp;
daddr_t *dp, *iaddrp;
int db_per_block, i, j;
u_long page_size;
#ifdef VERBOSE
printf("FILE INFOS\n");
#endif
db_per_block = fsbtodb(&fsp->fi_lfs, 1);
page_size = fsp->fi_lfs.lfs_bsize;
bp = seg_buf + datobyte(fsp, psegaddr - segaddr) + LFS_SUMMARY_SIZE;
bip += *countp;
psegaddr += bytetoda(fsp, LFS_SUMMARY_SIZE);
iaddrp = (daddr_t *)((caddr_t)sp + LFS_SUMMARY_SIZE);
--iaddrp;
for (fip = (FINFO *)(sp + 1), i = 0; i < sp->ss_nfinfo;
++i, fip = (FINFO *)(&fip->fi_blocks[fip->fi_nblocks])) {
ifp = IFILE_ENTRY(&fsp->fi_lfs, fsp->fi_ifilep, fip->fi_ino);
PRINT_FINFO(fip, ifp);
if (ifp->if_version > fip->fi_version)
continue;
dp = &(fip->fi_blocks[0]);
for (j = 0; j < fip->fi_nblocks; j++, dp++) {
while (psegaddr == *iaddrp) {
psegaddr += db_per_block;
bp += page_size;
--iaddrp;
}
bip->bi_inode = fip->fi_ino;
bip->bi_lbn = *dp;
bip->bi_daddr = psegaddr;
bip->bi_segcreate = (time_t)(sp->ss_create);
bip->bi_bp = bp;
bip->bi_version = ifp->if_version;
psegaddr += db_per_block;
bp += page_size;
++bip;
++(*countp);
}
}
}
/*
* For a particular segment summary, reads the inode blocks and adds
* INODE_INFO structures to the array. Returns the number of inodes
* actually added.
*/
void
add_inodes (fsp, bip, countp, sp, seg_buf, seg_addr)
FS_INFO *fsp; /* pointer to super block */
BLOCK_INFO *bip; /* block info array */
int *countp; /* pointer to current number of inodes */
SEGSUM *sp; /* segsum pointer */
caddr_t seg_buf; /* the buffer containing the segment's data */
daddr_t seg_addr; /* disk address of seg_buf */
{
struct dinode *di;
struct lfs *lfsp;
IFILE *ifp;
BLOCK_INFO *bp;
daddr_t *daddrp;
ino_t inum;
int i;
if (sp->ss_ninos <= 0)
return;
bp = bip + *countp;
lfsp = &fsp->fi_lfs;
#ifdef VERBOSE
(void) printf("INODES:\n");
#endif
daddrp = (daddr_t *)((caddr_t)sp + LFS_SUMMARY_SIZE);
for (i = 0; i < sp->ss_ninos; ++i) {
if (i % INOPB(lfsp) == 0) {
--daddrp;
di = (struct dinode *)(seg_buf +
((*daddrp - seg_addr) << fsp->fi_daddr_shift));
} else
++di;
inum = di->di_inumber;
bp->bi_lbn = LFS_UNUSED_LBN;
bp->bi_inode = inum;
bp->bi_daddr = *daddrp;
bp->bi_bp = di;
bp->bi_segcreate = sp->ss_create;
if (inum == LFS_IFILE_INUM) {
bp->bi_version = 1; /* Ifile version should be 1 */
bp++;
++(*countp);
PRINT_INODE(1, bp);
} else {
ifp = IFILE_ENTRY(lfsp, fsp->fi_ifilep, inum);
PRINT_INODE(ifp->if_daddr == *daddrp, bp);
bp->bi_version = ifp->if_version;
if (ifp->if_daddr == *daddrp) {
bp++;
++(*countp);
}
}
}
}
/*
* Checks the summary checksum and the data checksum to determine if the
* segment is valid or not. Returns the size of the partial segment if it
* is valid, * and 0 otherwise. Use dump_summary to figure out size of the
* the partial as well as whether or not the checksum is valid.
*/
int
pseg_valid (fsp, ssp)
FS_INFO *fsp; /* pointer to file system info */
SEGSUM *ssp; /* pointer to segment summary block */
{
caddr_t p;
int i, nblocks;
u_long *datap;
if ((nblocks = dump_summary(&fsp->fi_lfs, ssp, 0, NULL)) <= 0 ||
nblocks > fsp->fi_lfs.lfs_ssize - 1)
return(0);
/* check data/inode block(s) checksum too */
datap = (u_long *)malloc(nblocks * sizeof(u_long));
p = (caddr_t)ssp + LFS_SUMMARY_SIZE;
for (i = 0; i < nblocks; ++i) {
datap[i] = *((u_long *)p);
p += fsp->fi_lfs.lfs_bsize;
}
if (cksum ((void *)datap, nblocks * sizeof(u_long)) != ssp->ss_datasum)
return (0);
return (nblocks);
}
/* #define MMAP_SEGMENT */
/*
* read a segment into a memory buffer
*/
int
mmap_segment (fsp, segment, segbuf, use_mmap)
FS_INFO *fsp; /* file system information */
int segment; /* segment number */
caddr_t *segbuf; /* pointer to buffer area */
int use_mmap; /* mmap instead of read */
{
struct lfs *lfsp;
int fid; /* fildes for file system device */
daddr_t seg_daddr; /* base disk address of segment */
off_t seg_byte;
size_t ssize;
char mntfromname[MNAMELEN+2];
lfsp = &fsp->fi_lfs;
/* get the disk address of the beginning of the segment */
seg_daddr = sntoda(lfsp, segment);
seg_byte = datobyte(fsp, seg_daddr);
ssize = seg_size(lfsp);
strcpy(mntfromname, "/dev/r");
strcat(mntfromname, fsp->fi_statfsp->f_mntfromname+5);
if ((fid = open(mntfromname, O_RDONLY, (mode_t)0)) < 0) {
err(0, "mmap_segment: bad open");
return (-1);
}
if (use_mmap) {
*segbuf = mmap ((caddr_t)0, seg_size(lfsp), PROT_READ,
0, fid, seg_byte);
if (*(long *)segbuf < 0) {
err(0, "mmap_segment: mmap failed");
return (NULL);
}
} else {
#ifdef VERBOSE
printf("mmap_segment\tseg_daddr: %lu\tseg_size: %lu\tseg_offset: %qu\n",
seg_daddr, ssize, seg_byte);
#endif
/* malloc the space for the buffer */
*segbuf = malloc(ssize);
if (!*segbuf) {
err(0, "mmap_segment: malloc failed");
return(NULL);
}
/* read the segment data into the buffer */
if (lseek (fid, seg_byte, SEEK_SET) != seg_byte) {
err (0, "mmap_segment: bad lseek");
free(*segbuf);
return (-1);
}
if (read (fid, *segbuf, ssize) != ssize) {
err (0, "mmap_segment: bad read");
free(*segbuf);
return (-1);
}
}
close (fid);
return (0);
}
void
munmap_segment (fsp, seg_buf, use_mmap)
FS_INFO *fsp; /* file system information */
caddr_t seg_buf; /* pointer to buffer area */
int use_mmap; /* mmap instead of read/write */
{
if (use_mmap)
munmap (seg_buf, seg_size(&fsp->fi_lfs));
else
free (seg_buf);
}
/*
* USEFUL DEBUGGING TOOLS:
*/
void
print_SEGSUM (lfsp, p)
struct lfs *lfsp;
SEGSUM *p;
{
if (p)
(void) dump_summary(lfsp, p, DUMP_ALL, NULL);
else printf("0x0");
fflush(stdout);
}
int
bi_compare(a, b)
const void *a;
const void *b;
{
const BLOCK_INFO *ba, *bb;
int diff;
ba = a;
bb = b;
if (diff = (int)(ba->bi_inode - bb->bi_inode))
return (diff);
if (diff = (int)(ba->bi_lbn - bb->bi_lbn)) {
if (ba->bi_lbn == LFS_UNUSED_LBN)
return(-1);
else if (bb->bi_lbn == LFS_UNUSED_LBN)
return(1);
else if (ba->bi_lbn < 0 && bb->bi_lbn >= 0)
return(1);
else if (bb->bi_lbn < 0 && ba->bi_lbn >= 0)
return(-1);
else
return (diff);
}
if (diff = (int)(ba->bi_segcreate - bb->bi_segcreate))
return (diff);
diff = (int)(ba->bi_daddr - bb->bi_daddr);
return (diff);
}
int
bi_toss(dummy, a, b)
const void *dummy;
const void *a;
const void *b;
{
const BLOCK_INFO *ba, *bb;
ba = a;
bb = b;
return(ba->bi_inode == bb->bi_inode && ba->bi_lbn == bb->bi_lbn);
}
void
toss(p, nump, size, dotoss, client)
void *p;
int *nump;
size_t size;
int (*dotoss) __P((const void *, const void *, const void *));
void *client;
{
int i;
void *p1;
if (*nump == 0)
return;
for (i = *nump; --i > 0;) {
p1 = p + size;
if (dotoss(client, p, p1)) {
memmove(p, p1, i * size);
--(*nump);
} else
p += size;
}
}