sbin/fsck_lfs/pass0.c

1.1  perseant /* $Id: pass0.c,v 1.1 1999/03/18 02:02:19 perseant Exp $ */
1.1  perseant /*
1.1  perseant  * Copyright (c) 1998 Konrad E. Schroder.
1.1  perseant  * Copyright (c) 1980, 1986, 1993
1.1  perseant  *	The Regents of the University of California.  All rights reserved.
1.1  perseant  *
1.1  perseant  * Redistribution and use in source and binary forms, with or without
1.1  perseant  * modification, are permitted provided that the following conditions
1.1  perseant  * are met:
1.1  perseant  * 1. Redistributions of source code must retain the above copyright
1.1  perseant  *    notice, this list of conditions and the following disclaimer.
1.1  perseant  * 2. Redistributions in binary form must reproduce the above copyright
1.1  perseant  *    notice, this list of conditions and the following disclaimer in the
1.1  perseant  *    documentation and/or other materials provided with the distribution.
1.1  perseant  * 3. All advertising materials mentioning features or use of this software
1.1  perseant  *    must display the following acknowledgement:
1.1  perseant  *	This product includes software developed by the University of
1.1  perseant  *	California, Berkeley and its contributors.
1.1  perseant  * 4. Neither the name of the University nor the names of its contributors
1.1  perseant  *    may be used to endorse or promote products derived from this software
1.1  perseant  *    without specific prior written permission.
1.1  perseant  *
1.1  perseant  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
1.1  perseant  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.1  perseant  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.1  perseant  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
1.1  perseant  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.1  perseant  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.1  perseant  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.1  perseant  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.1  perseant  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1  perseant  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1  perseant  * SUCH DAMAGE.
1.1  perseant  */
1.1  perseant
1.1  perseant #include <sys/param.h>
1.1  perseant #include <sys/time.h>
1.1  perseant #include <ufs/ufs/dinode.h>
1.1  perseant #include <ufs/ufs/dir.h>
1.1  perseant #include <sys/mount.h>
1.1  perseant #include <ufs/lfs/lfs.h>
1.1  perseant #include <ufs/lfs/lfs_extern.h>
1.1  perseant
1.1  perseant #include <stdio.h>
1.1  perseant #include <stdlib.h>
1.1  perseant #include <string.h>
1.1  perseant
1.1  perseant #include "fsck.h"
1.1  perseant #include "extern.h"
1.1  perseant #include "fsutil.h"
1.1  perseant
1.1  perseant /* Flags for check_segment */
1.1  perseant #define CKSEG_VERBOSE     1
1.1  perseant #define CKSEG_IGNORECLEAN 2
1.1  perseant
1.1  perseant extern int fake_cleanseg;
1.1  perseant void check_segment(int, int, daddr_t, struct lfs *, int, int (*)(struct lfs *, SEGSUM *, int, int, daddr_t, daddr_t));
1.1  perseant static int check_summary(struct lfs *, SEGSUM *, int, int, daddr_t, daddr_t);
1.1  perseant SEGUSE *lfs_gseguse(int);
1.1  perseant
1.1  perseant struct dinode **din_table;
1.1  perseant SEGUSE *seg_table;
1.1  perseant /*
1.1  perseant  * Pass 0.  Check the LFS partial segments for valid checksums, correcting
1.1  perseant  * if necessary.  Also check for valid offsets for inode and finfo blocks.
1.1  perseant  */
1.1  perseant /* XXX more could be done here---consistency between inode-held blocks and
1.1  perseant    finfo blocks, for one thing. */
1.1  perseant
1.1  perseant #define dbshift (sblock.lfs_bshift - sblock.lfs_fsbtodb)
1.1  perseant
1.1  perseant void pass0()
1.1  perseant {
1.1  perseant     int i;
1.1  perseant     daddr_t seg_addr;
1.1  perseant
1.1  perseant     /*
1.1  perseant      * Run through the Ifile, to count and load the inodes into
1.1  perseant      * a dynamic inode table.
1.1  perseant      */
1.1  perseant
1.1  perseant     /*
1.1  perseant      * Check the segments
1.1  perseant      */
1.1  perseant
1.1  perseant     seg_addr = sblock.lfs_sboffs[0];
1.1  perseant     for(i=0; i < sblock.lfs_nseg; i++)
1.1  perseant     {
1.1  perseant 	    seg_table[i] = *(lfs_gseguse(i));
1.1  perseant 	    check_segment(fsreadfd, i, seg_addr, &sblock,
1.1  perseant 			  CKSEG_IGNORECLEAN|CKSEG_VERBOSE, check_summary);
1.1  perseant 	    seg_addr += (sblock.lfs_ssize << sblock.lfs_fsbtodb);
1.1  perseant     }
1.1  perseant #if 0
1.1  perseant     /* check to see which inodes we didn't get */
1.1  perseant     printf("Unavailable inodes: ");
1.1  perseant     for(i=1;i<maxino;i++) /* XXX ino 0 is never present */
1.1  perseant         if(din_table[i]==NULL)
1.1  perseant         {
1.1  perseant             struct ifile *ifp;
1.1  perseant
1.1  perseant             ifp = lfs_ientry(i);
1.1  perseant             printf("(%d should be at daddr 0x%x)",i,ifp->if_daddr);
1.1  perseant         }
1.1  perseant     putchar('\n');
1.1  perseant #endif
1.1  perseant }
1.1  perseant
1.1  perseant static void dump_segsum(SEGSUM *sump, daddr_t addr)
1.1  perseant {
1.1  perseant     printf("Dump partial summary block 0x%x\n",addr);
1.1  perseant     printf("\tsumsum:  %x (%d)\n",sump->ss_sumsum,sump->ss_sumsum);
1.1  perseant     printf("\tdatasum: %x (%d)\n",sump->ss_datasum,sump->ss_datasum);
1.1  perseant     printf("\tnext:    %x (%d)\n",sump->ss_next,sump->ss_next);
1.1  perseant     printf("\tcreate:  %x (%d)\n",sump->ss_create,sump->ss_create);
1.1  perseant     printf("\tnfinfo:  %x (%d)\n",sump->ss_nfinfo,sump->ss_nfinfo);
1.1  perseant     printf("\tninos:   %x (%d)\n",sump->ss_ninos,sump->ss_ninos);
1.1  perseant     printf("\tflags:   %c%c\n",
1.1  perseant            sump->ss_flags&SS_DIROP?'d':'-',
1.1  perseant            sump->ss_flags&SS_CONT?'c':'-');
1.1  perseant }
1.1  perseant
1.1  perseant void check_segment(int fd, int segnum, daddr_t addr, struct lfs *fs, int flags, int (*func)(struct lfs *, SEGSUM *, int, int, daddr_t, daddr_t))
1.1  perseant {
1.1  perseant     struct lfs *sbp;
1.1  perseant     SEGSUM *sump=NULL;
1.1  perseant     SEGUSE su;
1.1  perseant     struct bufarea *bp = NULL;
1.1  perseant     int psegnum=0, ninos=0;
1.1  perseant     off_t sum_offset, db_ssize;
1.1  perseant     int bc;
1.1  perseant
1.1  perseant     db_ssize = sblock.lfs_ssize << sblock.lfs_fsbtodb;
1.1  perseant     su = *(lfs_gseguse(segnum)); /* structure copy */
1.1  perseant
1.1  perseant     if(fake_cleanseg >= 0 && segnum == fake_cleanseg)
1.1  perseant         seg_table[segnum].su_flags &= ~SEGUSE_DIRTY;
1.1  perseant
1.1  perseant     /* printf("Seg at 0x%x\n",addr); */
1.1  perseant     if((flags & CKSEG_VERBOSE) && segnum*db_ssize + fs->lfs_sboffs[0] != addr)
1.1  perseant         pwarn("WARNING: segment begins at 0x%qx, should be 0x%qx\n",
1.1  perseant               (long long unsigned)addr, segnum*db_ssize + fs->lfs_sboffs[0]);
1.1  perseant     sum_offset = ((off_t)addr << dbshift);
1.1  perseant
1.1  perseant     /* If this segment should have a superblock, look for one */
1.1  perseant     if(su.su_flags & SEGUSE_SUPERBLOCK) {
1.1  perseant         bp = getddblk(sum_offset >> dbshift, LFS_SBPAD);
1.1  perseant         sum_offset += LFS_SBPAD;
1.1  perseant
1.1  perseant         /* check for a superblock -- XXX this is crude */
1.1  perseant         sbp = (struct lfs *)(bp->b_un.b_buf);
1.1  perseant         if(sbp->lfs_magic==LFS_MAGIC) {
1.1  perseant #if 0
1.1  perseant             if(sblock.lfs_tstamp == sbp->lfs_tstamp
1.1  perseant                && memcmp(sbp,&sblock,sizeof(*sbp))
1.1  perseant 	       && (flags & CKSEG_VERBOSE))
1.1  perseant                 pwarn("SUPERBLOCK MISMATCH SEGMENT %d\n", segnum);
1.1  perseant #endif
1.1  perseant         } else {
1.1  perseant 		if(flags & CKSEG_VERBOSE)
1.1  perseant 			pwarn("SEGMENT %d SUPERBLOCK INVALID\n",segnum);
1.1  perseant 		/* XXX allow to fix */
1.1  perseant         }
1.1  perseant         bp->b_flags &= ~B_INUSE;
1.1  perseant     }
1.1  perseant     /* XXX need to also check whether this one *should* be dirty */
1.1  perseant     if((flags & CKSEG_IGNORECLEAN) && (su.su_flags & SEGUSE_DIRTY)==0)
1.1  perseant         return;
1.1  perseant
1.1  perseant     while(1) {
1.1  perseant         if(su.su_nsums <= psegnum)
1.1  perseant             break;
1.1  perseant         bp = getddblk(sum_offset >> dbshift, LFS_SUMMARY_SIZE);
1.1  perseant         sump = (SEGSUM *)(bp->b_un.b_buf);
1.1  perseant 	if (sump->ss_magic != SS_MAGIC) {
1.1  perseant 		if(flags & CKSEG_VERBOSE)
1.1  perseant 			printf("PARTIAL SEGMENT %d SEGMENT %d BAD PARTIAL SEGMENT MAGIC (0x%x should be 0x%x)\n",
1.1  perseant 			       psegnum, segnum, sump->ss_magic, SS_MAGIC);
1.1  perseant                 bp->b_flags &= ~B_INUSE;
1.1  perseant 		break;
1.1  perseant 	}
1.1  perseant         if(sump->ss_sumsum != cksum(&sump->ss_datasum, LFS_SUMMARY_SIZE - sizeof(sump->ss_sumsum))) {
1.1  perseant 		if(flags & CKSEG_VERBOSE) {
1.1  perseant 			/* Corrupt partial segment */
1.1  perseant 			pwarn("CORRUPT PARTIAL SEGMENT %d/%d OF SEGMENT %d AT BLK 0x%qx",
1.1  perseant 			      psegnum, su.su_nsums, segnum, sum_offset>>dbshift);
1.1  perseant 			if(db_ssize < (sum_offset>>dbshift) - addr)
1.1  perseant 				pwarn(" (+0x%qx/0x%qx)",
1.1  perseant 				      ((sum_offset>>dbshift) - addr) - db_ssize,
1.1  perseant 				      db_ssize);
1.1  perseant 			else
1.1  perseant 				pwarn(" (-0x%qx/0x%qx)",
1.1  perseant 				      db_ssize - ((sum_offset>>dbshift) - addr),
1.1  perseant 				      db_ssize);
1.1  perseant 			pwarn("\n");
1.1  perseant 			dump_segsum(sump,sum_offset>>dbshift);
1.1  perseant 		}
1.1  perseant 		/* XXX fix it maybe */
1.1  perseant 		bp->b_flags &= ~B_INUSE;
1.1  perseant 		break; /* XXX could be throwing away data, but if this segsum
1.1  perseant 			* is invalid, how to know where the next summary
1.1  perseant 			* begins? */
1.1  perseant         }
1.1  perseant 	/*
1.1  perseant 	 * Good partial segment
1.1  perseant 	 */
1.1  perseant 	bc = (*func)(&sblock, sump, segnum, psegnum, addr, (daddr_t)(sum_offset>>dbshift));
1.1  perseant 	if(bc) {
1.1  perseant                 sum_offset += LFS_SUMMARY_SIZE + bc;
1.1  perseant                 ninos += (sump->ss_ninos + INOPB(&sblock)-1)/INOPB(&sblock);
1.1  perseant                 psegnum++;
1.1  perseant 	} else {
1.1  perseant                 bp->b_flags &= ~B_INUSE;
1.1  perseant                 break;
1.1  perseant 	}
1.1  perseant         bp->b_flags &= ~B_INUSE;
1.1  perseant     }
1.1  perseant     if(flags & CKSEG_VERBOSE) {
1.1  perseant 	    if(ninos != su.su_ninos)
1.1  perseant 		    pwarn("SEGMENT %d has %d ninos, not %d\n",
1.1  perseant 			  segnum, ninos, su.su_ninos);
1.1  perseant 	    if(psegnum != su.su_nsums)
1.1  perseant 		    pwarn("SEGMENT %d has %d summaries, not %d\n",
1.1  perseant 			  segnum, psegnum, su.su_nsums);
1.1  perseant     }
1.1  perseant
1.1  perseant     return;
1.1  perseant }
1.1  perseant
1.1  perseant static int check_summary(struct lfs *fs, SEGSUM *sp, int sn, int pn, daddr_t seg_addr, daddr_t pseg_addr)
1.1  perseant {
1.1  perseant     FINFO *fp;
1.1  perseant     int bc; /* Bytes in partial segment */
1.1  perseant     daddr_t *dp;
1.1  perseant     struct dinode *ip;
1.1  perseant     struct bufarea *bp;
1.1  perseant     int i, j, n;
1.1  perseant
1.1  perseant     /* printf("Pseg at 0x%x, %d inos, %d finfos\n",addr>>dbshift,sp->ss_ninos,sp->ss_nfinfo); */
1.1  perseant     /* We've already checked the sumsum, just do the data bounds and sum */
1.1  perseant     bc = ((sp->ss_ninos + INOPB(fs) - 1) / INOPB(fs)) << fs->lfs_bshift;
1.1  perseant     dp = (daddr_t *)sp;
1.1  perseant     dp += LFS_SUMMARY_SIZE / sizeof(daddr_t);
1.1  perseant     dp--;
1.1  perseant     i=0;
1.1  perseant #if 0
1.1  perseant     if(sp->ss_ninos==0 && sp->ss_nfinfo==0) {
1.1  perseant         pwarn("SEGMENT %d PSEG %d IS EMPTY\n",sn,pn);
1.1  perseant         return 0;
1.1  perseant     }
1.1  perseant #endif
1.1  perseant     while(i<sp->ss_ninos)
1.1  perseant     {
1.1  perseant         if(*dp < seg_addr || *dp > seg_addr + (sblock.lfs_ssize<<dbshift))
1.1  perseant         {
1.1  perseant             printf("Disk address 0x%x but should be in 0x%x--0x%x\n",
1.1  perseant                    *dp, seg_addr, seg_addr+(sblock.lfs_ssize<<dbshift));
1.1  perseant         }
1.1  perseant         bp = getddblk(*dp, (1<<fs->lfs_bshift));
1.1  perseant         ip = (struct dinode *)bp->b_un.b_buf;
1.1  perseant         for(j=0; i<sp->ss_ninos && j<INOPB(fs); j++) {
1.1  perseant             /* check range */
1.1  perseant             if(ip[j].di_inumber < 0 || ip[j].di_inumber > maxino)
1.1  perseant             {
1.1  perseant                 pwarn("BAD INUM %d IN SEGMENT %d PARTIAL %d\n",
1.1  perseant                       ip[j].di_inumber, sn, pn);
1.1  perseant                 /* XXX Allow to fix (zero) this */
1.1  perseant             } else {
1.1  perseant                 /* take a record of the highest-generation of each inode */
1.1  perseant                 n = ip[j].di_inumber;
1.1  perseant #if 1
1.1  perseant                 if(din_table[n]==NULL || din_table[n]->di_gen < ip[j].di_gen) {
1.1  perseant                     if(!din_table[n])
1.1  perseant                         din_table[n] = (struct dinode *)
1.1  perseant                             malloc(sizeof(struct dinode));
1.1  perseant                     memcpy(din_table[n],&ip[j],sizeof(struct dinode));
1.1  perseant                 }
1.1  perseant #endif
1.1  perseant             }
1.1  perseant             i++;
1.1  perseant         }
1.1  perseant         bp->b_flags &= ~B_INUSE;
1.1  perseant         dp--;
1.1  perseant     }
1.1  perseant     fp = (FINFO *)(sp + 1);
1.1  perseant     for(i=0; i<sp->ss_nfinfo; i++) {
1.1  perseant         bc +=  fp->fi_lastlength + ((fp->fi_nblocks-1) << fs->lfs_bshift);
1.1  perseant         /* XXX for now, ignore mismatches between segments' FINFO and IFILE */
1.1  perseant         dp = &(fp->fi_blocks[0]);
1.1  perseant         for(j=0; j<fp->fi_nblocks; j++) {
1.1  perseant             /* XXX check values against inodes' known block size */
1.1  perseant             dp++;
1.1  perseant         }
1.1  perseant         fp = (FINFO *)dp;
1.1  perseant     }
1.1  perseant     return bc;
1.1  perseant }