/* $NetBSD: cleanerd.c,v 1.34 2001/11/21 19:14:24 wiz 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 __COPYRIGHT("@(#) Copyright (c) 1992, 1993\n\ The Regents of the University of California. All rights reserved.\n"); #if 0 static char sccsid[] = "@(#)cleanerd.c 8.5 (Berkeley) 6/10/95"; #else __RCSID("$NetBSD: cleanerd.c,v 1.34 2001/11/21 19:14:24 wiz Exp $"); #endif #endif /* not lint */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "clean.h" char *special = "cleanerd"; int do_small = 0; int do_mmap = 0; int do_quit = 0; int stat_report = 0; int debug = 0; int segwait_timeout = 5*60; /* Five minutes */ double load_threshold = 0.2; int use_fs_idle = 0; struct cleaner_stats { double util_tot; double util_sos; int blocks_read; int blocks_written; int segs_cleaned; int segs_empty; int segs_error; } cleaner_stats; struct seglist { unsigned long sl_id; /* segment number */ unsigned long sl_cost; /* cleaning cost */ unsigned long sl_bytes; /* bytes in segment */ unsigned long sl_age; /* age in seconds */ }; struct tossstruct { struct lfs *lfs; int seg; }; typedef struct { int nsegs; /* number of segments */ struct seglist **segs; /* segment numbers, costs, etc */ int nb; /* total number of blocks */ BLOCK_INFO_15 *ba; /* accumulated block_infos */ caddr_t *buf; /* segment buffers */ } SEGS_AND_BLOCKS; #define CLEAN_BYTES 0x1 /* function prototypes for system calls; not sure where they should go */ int lfs_segwait(fsid_t *, struct timeval *); int lfs_segclean(fsid_t *, u_long); int lfs_bmapv(fsid_t *, BLOCK_INFO_15 *, int); int lfs_markv(fsid_t *, BLOCK_INFO_15 *, int); /* function prototypes */ int bi_tossold(const void *, const void *, const void *); int choose_segments(FS_INFO *, struct seglist *, unsigned long (*)(FS_INFO *, SEGUSE *)); void clean_fs(FS_INFO *, unsigned long (*)(FS_INFO *, SEGUSE *), int, long); int clean_loop(FS_INFO *, int, long); int add_segment(FS_INFO *, struct seglist *, SEGS_AND_BLOCKS *); int clean_segments(FS_INFO *, SEGS_AND_BLOCKS *); unsigned long cost_benefit(FS_INFO *, SEGUSE *); int cost_compare(const void *, const void *); void sig_report(int); void just_exit(int); int main(int, char *[]); /* * Cleaning Cost Functions: * * These return the cost of cleaning a segment. The higher the cost value * the better it is to clean the segment, so empty segments have the highest * cost. (It is probably better to think of this as a priority value * instead). * * This is the cost-benefit policy simulated and described in Rosenblum's * 1991 SOSP paper. */ unsigned long cost_benefit(FS_INFO *fsp, SEGUSE *su) { struct lfs *lfsp; struct timeval t; time_t age; unsigned long live; gettimeofday(&t, NULL); live = su->su_nbytes; age = t.tv_sec < su->su_lastmod ? 0 : t.tv_sec - su->su_lastmod; lfsp = &fsp->fi_lfs; if (live == 0) { /* No cost, only benefit. */ return lblkno(lfsp, seg_size(lfsp)) * t.tv_sec; } else if (su->su_flags & SEGUSE_ERROR) { /* No benefit: don't even try */ return 0; } else { /* * from lfsSegUsage.c (Mendel's code). * priority calculation is done using INTEGER arithmetic. * sizes are in BLOCKS (that is why we use lblkno below). * age is in seconds. * * priority = ((seg_size - live) * age) / (seg_size + live) */ if (live < 0 || live > seg_size(lfsp)) { syslog(LOG_WARNING,"bad segusage count: %ld", live); live = 0; } return (lblkno(lfsp, seg_size(lfsp) - live) * age) / lblkno(lfsp, seg_size(lfsp) + live); } } int main(int argc, char **argv) { FS_INFO *fsp; struct statfs *lstatfsp; /* file system stats */ struct timeval timeout; /* sleep timeout */ fsid_t fsid; long clean_opts; /* cleaning options */ int segs_per_clean; int opt, cmd_err; pid_t childpid; char *fs_name; /* name of filesystem to clean */ time_t now, lasttime; int loopcount; char *pidname; /* Name of pid file base */ char *cp; cmd_err = debug = do_quit = 0; clean_opts = 0; segs_per_clean = 1; while ((opt = getopt(argc, argv, "bdfl:mn:qr:st:")) != -1) { switch (opt) { case 'b': /* * Use live bytes to determine * how many segs to clean. */ clean_opts |= CLEAN_BYTES; break; case 'd': /* Debug mode. */ debug++; break; case 'f': use_fs_idle = 1; break; case 'l': /* Load below which to clean */ load_threshold = atof(optarg); break; case 'm': do_mmap = 1; break; case 'n': /* How many segs to clean at once */ segs_per_clean = atoi(optarg); break; case 'q': /* Quit after one run */ do_quit = 1; break; case 'r': /* Report every stat_report segments */ stat_report = atoi(optarg); break; case 's': /* small writes */ do_small = 1; break; case 't': segwait_timeout = atoi(optarg); break; default: ++cmd_err; } } argc -= optind; argv += optind; if (cmd_err || (argc != 1)) err(1, "usage: lfs_cleanerd [-bdms] [-l load] [-n nsegs] [-r report_freq] [-t timeout] fs_name"); fs_name = argv[0]; if (fs_getmntinfo(&lstatfsp, fs_name, MOUNT_LFS) == 0) { /* didn't find the filesystem */ err(1, "lfs_cleanerd: filesystem %s isn't an LFS!", fs_name); } openlog("lfs_cleanerd", LOG_NDELAY | LOG_PID | (debug ? LOG_PERROR : 0), LOG_DAEMON); /* should we become a daemon, chdir to / & close fd's */ if (debug == 0) { if (daemon(0, 0) == -1) err(1, "lfs_cleanerd: couldn't become a daemon!"); lasttime=0; loopcount=0; loop: if((childpid=fork())<0) { syslog(LOG_ERR,"%s: couldn't fork, exiting: %m", fs_name); exit(1); } if(childpid == 0) { /* Record child's pid */ pidname = malloc(strlen(fs_name) + 16); sprintf(pidname, "lfs_cleanerd:s:%s", fs_name); while((cp = strchr(pidname, '/')) != NULL) *cp = '|'; pidfile(pidname); } else { /* Record parent's pid */ pidname = malloc(strlen(fs_name) + 16); sprintf(pidname, "lfs_cleanerd:m:%s", fs_name); while((cp = strchr(pidname, '/')) != NULL) *cp = '|'; pidfile(pidname); signal(SIGINT, just_exit); wait(NULL); /* If the child is looping, give up */ ++loopcount; if((now=time(NULL)) - lasttime > TIME_THRESHOLD) { loopcount=0; } lasttime = now; if(loopcount > LOOP_THRESHOLD) { syslog(LOG_ERR,"%s: cleanerd looping, exiting", fs_name); exit(1); } if (fs_getmntinfo(&lstatfsp, fs_name, MOUNT_LFS) == 0) { /* fs has been unmounted(?); exit quietly */ syslog(LOG_ERR,"lfs_cleanerd: fs %s unmounted, exiting", fs_name); exit(0); } goto loop; } } signal(SIGINT, sig_report); signal(SIGUSR1, sig_report); signal(SIGUSR2, sig_report); if(debug) syslog(LOG_INFO,"Cleaner starting on filesystem %s", fs_name); timeout.tv_sec = segwait_timeout; timeout.tv_usec = 0; fsid.val[0] = 0; fsid.val[1] = 0; for (fsp = get_fs_info(lstatfsp, do_mmap); ; reread_fs_info(fsp, do_mmap)) { /* * clean the filesystem, and, if it needed cleaning * (i.e. it returned nonzero) try it again * to make sure that some nasty process hasn't just * filled the disk system up. */ if (clean_loop(fsp, segs_per_clean, clean_opts)) continue; fsid = lstatfsp->f_fsid; if(debug > 1) syslog(LOG_DEBUG,"Cleaner going to sleep."); if (lfs_segwait(&fsid, &timeout) < 0) syslog(LOG_WARNING,"lfs_segwait returned error."); if(debug > 1) syslog(LOG_DEBUG,"Cleaner waking up."); } } /* return the number of segments cleaned */ int clean_loop(FS_INFO *fsp, int nsegs, long options) { struct lfs *lfsp; double loadavg[MAXLOADS]; time_t now; u_long max_free_segs; u_long fsb_per_seg; lfsp = &fsp->fi_lfs; /* * Compute the maximum possible number of free segments, given the * number of free blocks. */ fsb_per_seg = segtod(lfsp, 1); max_free_segs = fsp->fi_cip->bfree / fsb_per_seg + lfsp->lfs_minfreeseg; /* * We will clean if there are not enough free blocks or total clean * space is less than BUSY_LIM % of possible clean space. */ now = time((time_t *)NULL); if(debug > 1) { syslog(LOG_DEBUG, "fsb_per_seg = %lu bfree = %u avail = %d," " bfree = %u, ", fsb_per_seg, fsp->fi_cip->bfree, fsp->fi_cip->avail, fsp->fi_cip->bfree); syslog(LOG_DEBUG, "clean segs = %d, max_free_segs = %ld", fsp->fi_cip->clean, max_free_segs); } if ((fsp->fi_cip->bfree - fsp->fi_cip->avail > fsb_per_seg && fsp->fi_cip->avail < (long)fsb_per_seg && fsp->fi_cip->bfree > (long)fsb_per_seg) || (fsp->fi_cip->clean < max_free_segs && (fsp->fi_cip->clean <= lfsp->lfs_minfreeseg || fsp->fi_cip->clean < max_free_segs * BUSY_LIM))) { if(debug) syslog(LOG_DEBUG, "Cleaner Running at %s" " (%d of %lu segments available, avail = %d," " bfree = %u)", ctime(&now), fsp->fi_cip->clean, max_free_segs, fsp->fi_cip->avail, fsp->fi_cip->bfree); clean_fs(fsp, cost_benefit, nsegs, options); if(do_quit) { if(debug) syslog(LOG_INFO,"Cleaner shutting down"); exit(0); } return (1); } else if(use_fs_idle) { /* * If we're using "filesystem idle" instead of system idle, * clean if the fs has not been modified in segwait_timeout * seconds. */ if(now-fsp->fi_fs_tstamp > segwait_timeout && fsp->fi_cip->clean < max_free_segs * IDLE_LIM) { if(debug) { syslog(LOG_DEBUG, "Cleaner Running at %s: " "fs idle time %ld sec; %d of %lu segments available)", ctime(&now), (long)now-fsp->fi_fs_tstamp, fsp->fi_cip->clean, max_free_segs); syslog(LOG_DEBUG, " filesystem idle since %s", ctime(&(fsp->fi_fs_tstamp))); } clean_fs(fsp, cost_benefit, nsegs, options); if(do_quit) { if(debug) syslog(LOG_INFO,"Cleaner shutting down"); exit(0); } return (1); } } else { /* * We will also clean if the system is reasonably idle and * the total clean space is less than IDLE_LIM % of possible * clean space. */ if (getloadavg(loadavg, MAXLOADS) == -1) { perror("getloadavg: failed"); return (-1); } if (loadavg[ONE_MIN] < load_threshold && fsp->fi_cip->clean < max_free_segs * IDLE_LIM) { if (debug) syslog(LOG_DEBUG, "Cleaner Running at %s " "(system load %.1f, %d of %lu segments available)", ctime(&now), loadavg[ONE_MIN], fsp->fi_cip->clean, max_free_segs); clean_fs(fsp, cost_benefit, nsegs, options); if (do_quit) { if(debug) syslog(LOG_INFO,"Cleaner shutting down"); exit(0); } return (1); } } if (debug > 1) { if (fsp->fi_cip->bfree - fsp->fi_cip->avail <= fsb_per_seg) syslog(LOG_DEBUG, "condition 1 false"); if (fsp->fi_cip->avail >= (long)fsb_per_seg) syslog(LOG_DEBUG, "condition 2 false"); if (fsp->fi_cip->clean >= max_free_segs) syslog(LOG_DEBUG, "condition 3 false"); if (fsp->fi_cip->clean > lfsp->lfs_minfreeseg) syslog(LOG_DEBUG, "condition 4 false"); if (fsp->fi_cip->clean >= max_free_segs * BUSY_LIM) syslog(LOG_DEBUG, "condition 5 false"); syslog(LOG_DEBUG, "Cleaner Not Running at %s", ctime(&now)); } return (0); } void clean_fs(FS_INFO *fsp, unsigned long (*cost_func)(FS_INFO *, SEGUSE *), int nsegs, long options) { struct seglist *segs, *sp; long int to_clean, cleaned_bytes; unsigned long i, j, total; struct rusage ru; fsid_t *fsidp; int error; SEGS_AND_BLOCKS *sbp; fsidp = &fsp->fi_statfsp->f_fsid; if ((segs = malloc(fsp->fi_lfs.lfs_nseg * sizeof(struct seglist))) == NULL) { syslog(LOG_WARNING,"malloc failed: %m"); return; } total = i = choose_segments(fsp, segs, cost_func); /* If we can get lots of cleaning for free, do it now */ sp = segs; for(j=0; j < total && sp->sl_bytes == 0; j++) { if(debug) syslog(LOG_DEBUG,"Wiping empty segment %ld",sp->sl_id); if(lfs_segclean(fsidp, sp->sl_id) < 0) syslog(LOG_WARNING,"lfs_segclean failed empty segment %ld: %m", sp->sl_id); ++cleaner_stats.segs_empty; sp++; i--; } if(j > nsegs) { free(segs); return; } #if 0 /* If we relly need to clean a lot, do it now */ if(fsp->fi_cip->clean < 2 * fsp->fi_lfs.lfs_minfreeseg) nsegs = MAX(nsegs, fsp->fi_lfs.lfs_minfreeseg); #endif /* But back down if we haven't got that many free to clean into */ if(fsp->fi_cip->clean < nsegs) nsegs = fsp->fi_cip->clean; if (debug > 1) syslog(LOG_DEBUG, "clean_fs: found %ld segments to clean in %s", i, fsp->fi_statfsp->f_mntonname); if (i) { sbp = (SEGS_AND_BLOCKS *)malloc(sizeof(SEGS_AND_BLOCKS)); memset(sbp, 0, sizeof(SEGS_AND_BLOCKS)); /* Check which cleaning algorithm to use. */ if (options & CLEAN_BYTES) { /* Count bytes */ cleaned_bytes = 0; to_clean = nsegs << fsp->fi_lfs.lfs_segshift; for (; i && cleaned_bytes < to_clean; i--, ++sp) { if (add_segment(fsp, sp, sbp) < 0) { syslog(LOG_WARNING,"add_segment failed" " segment %ld: %m", sp->sl_id); if (sbp->nsegs == 0 && errno != ENOENT) continue; else break; } cleaned_bytes += sp->sl_bytes; } } else { /* Count segments */ for (i = MIN(i, nsegs); i-- ; ++sp) { total--; syslog(LOG_DEBUG, "Cleaning segment %ld" " (of %ld choices)", sp->sl_id, i + 1); if (add_segment(fsp, sp, sbp) != 0) { syslog(LOG_WARNING,"add_segment failed" " segment %ld: %m", sp->sl_id); if (sbp->nsegs == 0 && errno != ENOENT) continue; else break; } } } if (clean_segments(fsp, sbp) >= 0) { for (j = 0; j < sbp->nsegs; j++) { sp = sbp->segs[j]; if (lfs_segclean(fsidp, sp->sl_id) < 0) syslog(LOG_WARNING, "lfs_segclean: segment %ld: %m", sp->sl_id); else syslog(LOG_DEBUG, "finished segment %ld", sp->sl_id); } } if (sbp->buf) free(sbp->buf); if (sbp->segs) free(sbp->segs); free(sbp); } free(segs); if(debug) { error = getrusage(RUSAGE_SELF, &ru); if(error) { syslog(LOG_WARNING, "getrusage returned error: %m"); } else { syslog(LOG_DEBUG, "Current usage: maxrss=%ld," " idrss=%ld, isrss=%ld", ru.ru_maxrss, ru.ru_idrss, ru.ru_isrss); } } } /* * Segment with the highest priority get sorted to the beginning of the * list. This sort assumes that empty segments always have a higher * cost/benefit than any utilized segment. */ int cost_compare(const void *a, const void *b) { return ((struct seglist *)b)->sl_cost < ((struct seglist *)a)->sl_cost ? -1 : 1; } /* * Returns the number of segments to be cleaned with the elements of seglist * filled in. */ int choose_segments(FS_INFO *fsp, struct seglist *seglist, unsigned long (*cost_func)(FS_INFO *, SEGUSE *)) { struct lfs *lfsp; struct seglist *sp; SEGUSE *sup; int i, nsegs; lfsp = &fsp->fi_lfs; if (debug > 1) syslog(LOG_DEBUG,"Entering choose_segments"); dump_super(lfsp); dump_cleaner_info(fsp->fi_cip); for (sp = seglist, i = 0; i < lfsp->lfs_nseg; ++i) { if (debug > 1) { printf("%d...", i); fflush(stdout); } sup = SEGUSE_ENTRY(lfsp, fsp->fi_segusep, i); if (debug > 2) PRINT_SEGUSE(sup, i); if (!(sup->su_flags & SEGUSE_DIRTY) || sup->su_flags & SEGUSE_ACTIVE) continue; if (debug > 2) syslog(LOG_DEBUG, "\tchoosing segment %d", i); sp->sl_cost = (*cost_func)(fsp, sup); sp->sl_id = i; sp->sl_bytes = sup->su_nbytes; sp->sl_age = time(NULL) - sup->su_lastmod; ++sp; } nsegs = sp - seglist; if (debug > 1) { putchar('\n'); syslog(LOG_DEBUG, "Sorting..."); } qsort(seglist, nsegs, sizeof(struct seglist), cost_compare); if (debug > 2) for(i = 0; i < nsegs; i++) { syslog(LOG_DEBUG, "%d: segment %lu age %lu" " contains %lu priority %lu\n", i, seglist[i].sl_age, seglist[i].sl_id, seglist[i].sl_bytes, seglist[i].sl_cost); } if (debug > 1) syslog(LOG_DEBUG,"Returning %d segments", nsegs); return (nsegs); } /* * Add still-valid blocks from the given segment to the block array, * in preparation for sending through lfs_markv. */ int add_segment(FS_INFO *fsp, struct seglist *slp, SEGS_AND_BLOCKS *sbp) { int id = slp->sl_id; BLOCK_INFO_15 *tba, *_bip; SEGUSE *sp; struct lfs *lfsp; struct tossstruct t; struct dinode *dip; caddr_t seg_buf; caddr_t cmp_buf, cmp_dp; size_t size; daddr_t seg_addr; int num_blocks, i, j, error; int seg_isempty=0; unsigned long *lp; lfsp = &fsp->fi_lfs; sp = SEGUSE_ENTRY(lfsp, fsp->fi_segusep, id); seg_addr = sntod(lfsp,id); error = 0; tba = NULL; if (debug) syslog(LOG_DEBUG, "adding segment %d: contains %lu bytes", id, (unsigned long)sp->su_nbytes); /* XXX could add debugging to verify that segment is really empty */ if (sp->su_nbytes == 0) { ++cleaner_stats.segs_empty; ++seg_isempty; } /* Add a new segment to the accumulated list */ sbp->nsegs++; sbp->segs = (struct seglist **)realloc(sbp->segs, sizeof(struct seglist *) * sbp->nsegs); sbp->buf = (caddr_t *)realloc(sbp->buf, sizeof(caddr_t) * sbp->nsegs); sbp->segs[sbp->nsegs - 1] = slp; /* map the segment into a buffer */ if (mmap_segment(fsp, id, &seg_buf, do_mmap) < 0) { syslog(LOG_WARNING,"add_segment: mmap_segment failed: %m"); ++cleaner_stats.segs_error; --sbp->nsegs; return (-1); } sbp->buf[sbp->nsegs - 1] = seg_buf; /* get a list of blocks that are contained by the segment */ if ((error = lfs_segmapv(fsp, id, seg_buf, &tba, &num_blocks)) < 0) { syslog(LOG_WARNING, "add_segment: lfs_segmapv failed for segment %d", id); goto out; } cleaner_stats.blocks_read += segtod(lfsp, 1); if (debug > 1) syslog(LOG_DEBUG, "lfs_segmapv returned %d blocks", num_blocks); /* get the current disk address of blocks contained by the segment */ if ((error = lfs_bmapv(&fsp->fi_statfsp->f_fsid, tba, num_blocks)) < 0) { syslog(LOG_WARNING, "add_segment: lfs_bmapv failed"); goto out; } /* Now toss any blocks not in the current segment */ t.lfs = lfsp; t.seg = id; toss(tba, &num_blocks, sizeof(BLOCK_INFO_15), bi_tossold, &t); /* Check if last element should be tossed */ if (num_blocks && bi_tossold(&t, tba + num_blocks - 1, NULL)) --num_blocks; if(seg_isempty) { if(num_blocks) syslog(LOG_WARNING,"segment %d was supposed to be empty, but has %d live blocks!", id, num_blocks); else syslog(LOG_DEBUG,"segment %d is empty, as claimed", id); } /* XXX KS - check for misplaced blocks */ for(i=0; ifi_lfs), tba[i].bi_daddr) == id) { syslog(LOG_ERR, "bi_daddr = 0x%x = %db; %p - %p = %ld", tba[i].bi_daddr, fsbtob(lfsp, tba[i].bi_daddr - seg_addr), tba[i].bi_bp, seg_buf, (long)(((char *)(tba[i].bi_bp) - seg_buf))); syslog(LOG_ERR, "seg %d (0x%x), ino %d lbn %d, 0x%x != 0x%lx", id, seg_addr, tba[i].bi_inode, tba[i].bi_lbn, tba[i].bi_daddr, (long)seg_addr + btofsb(lfsp, (char *)(tba[i].bi_bp) - seg_buf)); error = EFAULT; goto out; /* * XXX KS - have to be careful here about Inodes; * if lfs_bmapv shows them somewhere else in the * segment from where we thought, we need to reload * the *right* inode, not the first one in the block. */ if(tba[i].bi_lbn == LFS_UNUSED_LBN) { dip = (struct dinode *)(seg_buf + fsbtob(lfsp, tba[i].bi_daddr - seg_addr)); for(j=INOPB(lfsp)-1;j>=0;j--) { if(dip[j].di_u.inumber == tba[i].bi_inode) { tba[i].bi_bp = (char *)(dip+j); break; } } if(j<0) { syslog(LOG_ERR, "lost inode %d in the shuffle! (blk %d)", tba[i].bi_inode, tba[i].bi_daddr); if (debug) { syslog(LOG_DEBUG, "inode numbers found were:"); for(j=INOPB(lfsp)-1;j>=0;j--) { syslog(LOG_DEBUG, "%d", dip[j].di_u.inumber); } } err(1,"lost inode"); } else if (debug > 1) { syslog(LOG_DEBUG,"Ino %d corrected to 0x%x", tba[i].bi_inode, tba[i].bi_daddr); } } else { tba[i].bi_bp = seg_buf + fsbtob(lfsp, tba[i].bi_daddr - seg_addr); } } } /* Update live bytes calc - XXX KS */ slp->sl_bytes = 0; for(i=0; isl_bytes += sizeof(struct dinode); else slp->sl_bytes += tba[i].bi_size; if(debug > 1) { syslog(LOG_DEBUG, "after bmapv still have %d blocks", num_blocks); if (num_blocks) syslog(LOG_DEBUG, "BLOCK INFOS"); for (_bip = tba, i=0; i < num_blocks; ++_bip, ++i) { PRINT_BINFO(_bip); lp = (u_long *)_bip->bi_bp; } } /* Compress segment buffer, if necessary */ if (!do_mmap && slp->sl_bytes < seg_size(lfsp) / 2) { if (debug > 1) syslog(LOG_DEBUG, "compressing: %d < %d", (int)slp->sl_bytes, seg_size(lfsp) / 2); cmp_buf = malloc(slp->sl_bytes); /* XXX could do in-place */ if (cmp_buf == NULL) { if (debug) syslog(LOG_DEBUG, "can't compress segment: %m"); } else { cmp_dp = cmp_buf; for (i = 0; i < num_blocks; i++) { if(tba[i].bi_lbn == LFS_UNUSED_LBN) size = sizeof(struct dinode); else size = tba[i].bi_size; memcpy(cmp_dp, tba[i].bi_bp, size); tba[i].bi_bp = cmp_dp; cmp_dp += size; } free(seg_buf); seg_buf = cmp_buf; sbp->buf[sbp->nsegs - 1] = seg_buf; } } /* Add these blocks to the accumulated list */ sbp->ba = realloc(sbp->ba, (sbp->nb + num_blocks) * sizeof(BLOCK_INFO_15)); memcpy(sbp->ba + sbp->nb, tba, num_blocks * sizeof(BLOCK_INFO_15)); sbp->nb += num_blocks; free(tba); return (0); out: --sbp->nsegs; if (tba) free(tba); if (error) { sp->su_flags |= SEGUSE_ERROR; ++cleaner_stats.segs_error; } munmap_segment(fsp, sbp->buf[sbp->nsegs], do_mmap); if (stat_report && cleaner_stats.segs_cleaned % stat_report == 0) sig_report(SIGUSR1); return (error); } /* Call markv and clean up */ int clean_segments(FS_INFO *fsp, SEGS_AND_BLOCKS *sbp) { int maxblocks, clean_blocks; BLOCK_INFO_15 *bp; int i, error; double util; error = 0; cleaner_stats.segs_cleaned += sbp->nsegs; cleaner_stats.blocks_written += sbp->nb; util = ((double)sbp->nb / segtod(&fsp->fi_lfs, 1)); cleaner_stats.util_tot += util; cleaner_stats.util_sos += util * util; if (do_small) maxblocks = MAXPHYS / fsp->fi_lfs.lfs_bsize - 1; else maxblocks = sbp->nb; for (bp = sbp->ba; sbp->nb > 0; bp += clean_blocks) { clean_blocks = maxblocks < sbp->nb ? maxblocks : sbp->nb; if ((error = lfs_markv(&fsp->fi_statfsp->f_fsid, bp, clean_blocks)) < 0) { syslog(LOG_WARNING,"clean_segment: lfs_markv failed: %m"); ++cleaner_stats.segs_error; if (errno == ENOENT) break; } sbp->nb -= clean_blocks; } /* Clean up */ if (sbp->ba) free(sbp->ba); if (error) ++cleaner_stats.segs_error; for (i = 0; i < sbp->nsegs; i++) munmap_segment(fsp, sbp->buf[i], do_mmap); if (stat_report && cleaner_stats.segs_cleaned % stat_report == 0) sig_report(SIGUSR1); return (error); } int bi_tossold(const void *client, const void *a, const void *b) { const struct tossstruct *t; t = (struct tossstruct *)client; return (((BLOCK_INFO_15 *)a)->bi_daddr == LFS_UNUSED_DADDR || dtosn(t->lfs, ((BLOCK_INFO_15 *)a)->bi_daddr) != t->seg); } void sig_report(int sig) { double avg = 0.0; syslog(LOG_INFO, "lfs_cleanerd:\t%s%d\n\t\t%s%d\n\t\t%s%d\n\t\t%s%d\n\t\t%s%d", "blocks_read ", cleaner_stats.blocks_read, "blocks_written ", cleaner_stats.blocks_written, "segs_cleaned ", cleaner_stats.segs_cleaned, "segs_empty ", cleaner_stats.segs_empty, "seg_error ", cleaner_stats.segs_error); syslog(LOG_INFO, "\t\t%s%5.2f\n\t\t%s%5.2f", "util_tot ", cleaner_stats.util_tot, "util_sos ", cleaner_stats.util_sos); avg = cleaner_stats.util_tot / MAX(cleaner_stats.segs_cleaned, 1.0); syslog(LOG_INFO, "\t\tavg util: %4.2f std dev: %9.6f", avg, cleaner_stats.util_sos / MAX(cleaner_stats.segs_cleaned - avg * avg, 1.0)); if (sig == SIGUSR2) { cleaner_stats.blocks_read = 0; cleaner_stats.blocks_written = 0; cleaner_stats.segs_cleaned = 0; cleaner_stats.segs_empty = 0; cleaner_stats.segs_error = 0; cleaner_stats.util_tot = 0.0; cleaner_stats.util_sos = 0.0; } if (sig == SIGINT) exit(0); } void just_exit(int sig) { exit(0); }