/* $NetBSD: library.c,v 1.17 2000/11/03 17:52:56 perseant Exp $ */ /*- * 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. */ #include #ifndef lint #if 0 static char sccsid[] = "@(#)library.c 8.3 (Berkeley) 5/24/95"; #else __RCSID("$NetBSD: library.c,v 1.17 2000/11/03 17:52:56 perseant Exp $"); #endif #endif /* not lint */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #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 *, daddr_t)); int pseg_size __P((daddr_t, FS_INFO *, SEGSUM *)); void print_SEGSUM __P((struct lfs *, SEGSUM *, daddr_t)); extern int debug; extern u_long cksum __P((void *, size_t)); /* XXX */ static int ifile_fd; static int dev_fd; /* * 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; const char *type; { /* allocate space for the filesystem info */ *buf = (struct statfs *)malloc(sizeof(struct statfs)); if (*buf == NULL) return 0; /* grab the filesystem info */ if (ifile_fd <= 0) { if (statfs(name, *buf) < 0) { free(*buf); return 0; } } else if(fstatfs(ifile_fd, *buf) < 0) { free(*buf); return 0; } /* check to see if it's the one we want */ if (strncmp(type, (*buf)->f_fstypename, MFSNAMELEN) || 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; fsp = (FS_INFO *)malloc(sizeof(FS_INFO)); if (fsp == NULL) return NULL; memset(fsp, 0, sizeof(FS_INFO)); fsp->fi_statfsp = lstatfsp; if (get_superblock (fsp, &fsp->fi_lfs)) { syslog(LOG_ERR, "Exiting: get_fs_info: get_superblock failed: %m"); exit(1); } 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; { if (ifile_fd <= 0) { if (fstatfs(ifile_fd, fsp->fi_statfsp)) { syslog(LOG_ERR, "Exiting: reread_fs_info: fstatfs failed: %m"); exit(1); } } else if (statfs(fsp->fi_statfsp->f_mntonname, fsp->fi_statfsp)) { syslog(LOG_ERR, "Exiting: reread_fs_info: statfs failed: %m"); exit(1); } 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]; char buf[LFS_SBPAD]; strcpy(mntfromname, "/dev/r"); strcat(mntfromname, fsp->fi_statfsp->f_mntfromname+5); if(dev_fd <= 0) { if ((dev_fd = open(mntfromname, O_RDONLY, (mode_t)0)) < 0) { syslog(LOG_WARNING,"get_superblock: bad open: %m"); return (-1); } } else lseek(dev_fd, 0, SEEK_SET); get(dev_fd, LFS_LABELPAD, buf, LFS_SBPAD); memcpy(&(sbp->lfs_dlfs), buf, sizeof(struct dlfs)); /* 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; struct statfs statfsbuf; caddr_t ifp; char *ifile_name; int count; 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(ifile_fd <= 0) { /* XXX KS - Do we ever *write* to the ifile? */ if ((ifile_fd = open(ifile_name, O_RDONLY, (mode_t)0)) < 0) { syslog(LOG_ERR, "Exiting: get_ifile: bad open: %m"); exit(1); } } else lseek(ifile_fd, 0, SEEK_SET); if (fstat (ifile_fd, &file_stat)) { /* If the fs was unmounted, don't complain */ statfs(fsp->fi_statfsp->f_mntonname, &statfsbuf); if(memcmp(&statfsbuf.f_fsid,&fsp->fi_statfsp->f_fsid, sizeof(statfsbuf.f_fsid))!=0) { /* Filesystem still mounted, this error is real */ syslog(LOG_ERR, "Exiting: get_ifile: fstat failed: %m"); exit(1); } exit(0); } fsp->fi_fs_tstamp = file_stat.st_mtimespec.tv_sec; if (use_mmap && file_stat.st_size == fsp->fi_ifile_length) { /* (void) close(fid); */ free(ifile_name); return; } /* get the ifile */ if (use_mmap) { if (fsp->fi_cip) munmap((caddr_t)fsp->fi_cip, fsp->fi_ifile_length); /* XXX KS - Do we ever *write* to the ifile? */ ifp = mmap ((caddr_t)0, file_stat.st_size, PROT_READ, MAP_FILE|MAP_PRIVATE, ifile_fd, (off_t)0); if (ifp == (caddr_t)(-1)) { syslog(LOG_ERR, "Exiting: get_ifile: mmap failed: %m"); exit(1); } } else { if (fsp->fi_cip) free(fsp->fi_cip); if (!(ifp = malloc (file_stat.st_size))) { syslog(LOG_ERR, "Exiting: get_ifile: malloc failed: %m"); exit(1); } redo_read: count = read (ifile_fd, ifp, (size_t) file_stat.st_size); if (count < 0) { syslog(LOG_ERR, "Exiting: get_ifile: bad ifile read: %m"); exit(1); } else if (count < file_stat.st_size) { syslog(LOG_WARNING, "get_ifile: %m"); if (lseek(ifile_fd, 0, SEEK_SET) < 0) { syslog(LOG_ERR, "Exiting: get_ifile: bad ifile lseek: %m"); exit(1); } 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 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); } /* * Return the size of the partial segment, in bytes. */ int pseg_size(pseg_addr, fsp, sp) daddr_t pseg_addr; /* base address of the segsum */ FS_INFO *fsp; /* Filesystem info */ SEGSUM *sp; /* the segsum */ { int i, ssize = 0; struct lfs *lfsp; FINFO *fp; lfsp = &fsp->fi_lfs; ssize = LFS_SUMMARY_SIZE + howmany(sp->ss_ninos, INOPB(lfsp)) * lfsp->lfs_bsize; for (fp = (FINFO *)(sp + 1), i = 0; i < sp->ss_nfinfo; ++i) { ssize += (fp->fi_nblocks-1) * lfsp->lfs_bsize + fp->fi_lastlength; fp = (FINFO *)(&fp->fi_blocks[fp->fi_nblocks]); } return ssize; } /* * This function will scan a segment and return a list of * 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, *_bip; SEGSUM *sp; SEGUSE *sup; FINFO *fip; struct lfs *lfsp; caddr_t s; daddr_t pseg_addr, seg_addr; int nelem, nblocks, nsegs, sumsize, i, ssize; i = 0; bip = NULL; 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); if(debug > 1) syslog(LOG_DEBUG, "\tsegment buffer at: %p\tseg_addr 0x%x", s, seg_addr); *bcount = 0; for (nsegs = 0; nsegs < sup->su_nsums; nsegs++) { sp = (SEGSUM *)s; nblocks = pseg_valid(fsp, sp, pseg_addr); if (nblocks <= 0) { syslog(LOG_DEBUG, "Warning: invalid segment summary at 0x%x", pseg_addr); goto err0; } #ifdef DIAGNOSTIC /* Verify size of summary block */ sumsize = sizeof(SEGSUM) + (sp->ss_ninos + INOPB(lfsp) - 1) / INOPB(lfsp); for (i = 0, 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) { syslog(LOG_ERR, "Exiting: 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); ssize = pseg_size(pseg_addr, fsp, sp); s += ssize; pseg_addr += btodb(ssize); /* XXX was bytetoda(fsp,ssize) */ } if(nsegs < sup->su_nsums) { syslog(LOG_NOTICE,"only %d segment summaries in seg %d (expected %d)", nsegs, seg, sup->su_nsums); goto err0; } qsort(bip, *bcount, sizeof(BLOCK_INFO), bi_compare); toss(bip, bcount, sizeof(BLOCK_INFO), bi_toss, NULL); if(debug > 1) { syslog(LOG_DEBUG, "BLOCK INFOS"); for (_bip = bip, i=0; i < *bcount; ++_bip, ++i) PRINT_BINFO(_bip); } *blocks = bip; return (0); err0: if (bip) free(bip); *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; int db_frag; u_long page_size; if(debug > 1) syslog(LOG_DEBUG, "FILE INFOS"); 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++) { /* Skip over intervening inode blocks */ 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; if (j < fip->fi_nblocks-1 || fip->fi_lastlength == page_size) { bip->bi_size = page_size; psegaddr += db_per_block; bp += page_size; } else { db_frag = fragstodb(&(fsp->fi_lfs), numfrags(&(fsp->fi_lfs), fip->fi_lastlength)); if(debug > 1) { syslog(LOG_DEBUG, "lastlength, frags: %d, %d", fip->fi_lastlength, db_frag); } bip->bi_size = fip->fi_lastlength; bp += fip->fi_lastlength; psegaddr += db_frag; } ++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 = NULL; /* XXX gcc */ 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; if(debug > 1) syslog(LOG_DEBUG, "INODES:"); 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; bp->bi_size = i; /* XXX KS - kludge */ 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, addr) FS_INFO *fsp; /* pointer to file system info */ SEGSUM *ssp; /* pointer to segment summary block */ daddr_t addr; /* address of the summary block on disk */ { int nblocks; #if 0 caddr_t p; int i; u_long *datap; #endif if (ssp->ss_magic != SS_MAGIC) { syslog(LOG_DEBUG, "Bad magic number: 0x%x instead of 0x%x", ssp->ss_magic, SS_MAGIC); return(0); } if ((nblocks = dump_summary(&fsp->fi_lfs, ssp, 0, NULL, addr)) <= 0 || nblocks > fsp->fi_lfs.lfs_ssize - 1) return(0); #if 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) { syslog(LOG_DEBUG, "Bad data checksum"); free(datap); return 0; } #endif 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; 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(dev_fd <= 0) { if ((dev_fd = open(mntfromname, O_RDONLY, (mode_t)0)) < 0) { syslog(LOG_WARNING,"mmap_segment: bad open: %m"); return (-1); } } else lseek(dev_fd, 0, SEEK_SET); if (use_mmap) { *segbuf = mmap ((caddr_t)0, seg_size(lfsp), PROT_READ, MAP_FILE|MAP_SHARED, dev_fd, seg_byte); if (*(long *)segbuf < 0) { syslog(LOG_WARNING,"mmap_segment: mmap failed: %m"); return (0); } } else { if(debug > 1) syslog(LOG_DEBUG, "mmap_segment\tseg_daddr: %lu\tseg_size: %lu\tseg_offset: %qu", (u_long)seg_daddr, (u_long)ssize, (long long)seg_byte); /* malloc the space for the buffer */ *segbuf = malloc(ssize); if (!*segbuf) { syslog(LOG_WARNING,"mmap_segment: malloc failed: %m"); return (0); } /* read the segment data into the buffer */ if (lseek (dev_fd, seg_byte, SEEK_SET) != seg_byte) { syslog(LOG_WARNING,"mmap_segment: bad lseek: %m"); free(*segbuf); return (-1); } if (read (dev_fd, *segbuf, ssize) != ssize) { syslog(LOG_WARNING,"mmap_segment: bad read: %m"); 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, addr) struct lfs *lfsp; SEGSUM *p; daddr_t addr; { if (p) (void) dump_summary(lfsp, p, DUMP_ALL, NULL, addr); else syslog(LOG_DEBUG, "0x0"); } 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); if ((diff = (int)(ba->bi_daddr - bb->bi_daddr))) return (diff); if(ba->bi_inode != LFS_IFILE_INUM) syslog(LOG_DEBUG,"bi_compare: using kludge on ino %d!", ba->bi_inode); diff = ba->bi_size - bb->bi_size; 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; char *p0, *p1; if (*nump == 0) return; p0 = p; for (i = *nump; --i > 0;) { p1 = p0 + size; if (dotoss(client, p0, p1)) { memmove(p0, p1, i * size); --(*nump); } else p0 += size; } }