/* * Copyright (c) 1997-2004 Erez Zadok * Copyright (c) 1989 Jan-Simon Pendry * Copyright (c) 1989 Imperial College of Science, Technology & Medicine * Copyright (c) 1989 The Regents of the University of California. * All rights reserved. * * This code is derived from software contributed to Berkeley by * Jan-Simon Pendry at Imperial College, London. * * 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 acknowledgment: * 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. * * %W% (Berkeley) %G% * * $Id: fsi_analyze.c,v 1.3.2.5 2004/01/06 03:15:23 ezk Exp $ * */ /* * Analyze filesystem declarations * * Note: most of this is magic! */ #ifdef HAVE_CONFIG_H # include #endif /* HAVE_CONFIG_H */ #include #include #include char *disk_fs_strings[] = { "fstype", "opts", "dumpset", "passno", "freq", "mount", "log", 0, }; char *mount_strings[] = { "volname", "exportfs", 0, }; char *fsmount_strings[] = { "as", "volname", "fstype", "opts", "from", 0, }; char *host_strings[] = { "host", "netif", "config", "arch", "cluster", "os", 0, }; char *ether_if_strings[] = { "inaddr", "netmask", "hwaddr", 0, }; /* * Strip off the trailing part of a domain * to produce a short-form domain relative * to the local host domain. * Note that this has no effect if the domain * names do not have the same number of * components. If that restriction proves * to be a problem then the loop needs recoding * to skip from right to left and do partial * matches along the way -- ie more expensive. */ void domain_strip(char *otherdom, char *localdom) { char *p1, *p2; if ((p1 = strchr(otherdom, '.')) && (p2 = strchr(localdom, '.')) && STREQ(p1 + 1, p2 + 1)) *p1 = '\0'; } /* * Take a little-endian domain name and * transform into a big-endian Un*x pathname. * For example: kiska.doc.ic -> ic/doc/kiska */ static char * compute_hostpath(char *hn) { char *p = strdup(hn); char *d; char path[MAXPATHLEN]; domain_strip(p, hostname); path[0] = '\0'; do { d = strrchr(p, '.'); if (d) { *d = 0; strcat(path, d + 1); strcat(path, "/"); } else { strcat(path, p); } } while (d); fsi_log("hostpath of '%s' is '%s'", hn, path); strcpy(p, path); return p; } static dict_ent * find_volname(char *nn) { dict_ent *de; char *p = strdup(nn); char *q; do { fsi_log("Searching for volname %s", p); de = dict_locate(dict_of_volnames, p); q = strrchr(p, '/'); if (q) *q = '\0'; } while (!de && q); XFREE(p); return de; } static void show_required(ioloc *l, int mask, char *info, char *hostname, char *strings[]) { int i; fsi_log("mask left for %s:%s is %#x", hostname, info, mask); for (i = 0; strings[i]; i++) if (ISSET(mask, i)) lerror(l, "%s:%s needs field \"%s\"", hostname, info, strings[i]); } /* * Check and fill in "exportfs" details. * Make sure the m_exported field references * the most local node with an "exportfs" entry. */ static int check_exportfs(qelem *q, fsi_mount *e) { fsi_mount *mp; int errors = 0; ITER(mp, fsi_mount, q) { if (ISSET(mp->m_mask, DM_EXPORTFS)) { if (e) lwarning(mp->m_ioloc, "%s has duplicate exportfs data", mp->m_name); mp->m_exported = mp; if (!ISSET(mp->m_mask, DM_VOLNAME)) set_mount(mp, DM_VOLNAME, strdup(mp->m_name)); } else { mp->m_exported = e; } /* * Recursively descend the mount tree */ if (mp->m_mount) errors += check_exportfs(mp->m_mount, mp->m_exported); /* * If a volume name has been specified, but this node and none * of its parents has been exported, report an error. */ if (ISSET(mp->m_mask, DM_VOLNAME) && !mp->m_exported) { lerror(mp->m_ioloc, "%s has a volname but no exportfs data", mp->m_name); errors++; } } return errors; } static int analyze_dkmount_tree(qelem *q, fsi_mount *parent, disk_fs *dk) { fsi_mount *mp; int errors = 0; ITER(mp, fsi_mount, q) { fsi_log("Mount %s:", mp->m_name); if (parent) { char n[MAXPATHLEN]; sprintf(n, "%s/%s", parent->m_name, mp->m_name); if (*mp->m_name == '/') lerror(mp->m_ioloc, "sub-directory %s of %s starts with '/'", mp->m_name, parent->m_name); else if (STREQ(mp->m_name, "default")) lwarning(mp->m_ioloc, "sub-directory of %s is named \"default\"", parent->m_name); fsi_log("Changing name %s to %s", mp->m_name, n); XFREE(mp->m_name); mp->m_name = strdup(n); } mp->m_name_len = strlen(mp->m_name); mp->m_parent = parent; mp->m_dk = dk; if (mp->m_mount) analyze_dkmount_tree(mp->m_mount, mp, dk); } return errors; } /* * The mount tree is a singleton list * containing the top-level mount * point for a disk. */ static int analyze_dkmounts(disk_fs *dk, qelem *q) { int errors = 0; fsi_mount *mp, *mp2 = 0; int i = 0; /* * First scan the list of subdirs to make * sure there is only one - and remember it */ if (q) { ITER(mp, fsi_mount, q) { mp2 = mp; i++; } } /* * Check... */ if (i < 1) { lerror(dk->d_ioloc, "%s:%s has no mount point", dk->d_host->h_hostname, dk->d_dev); return 1; } if (i > 1) { lerror(dk->d_ioloc, "%s:%s has more than one mount point", dk->d_host->h_hostname, dk->d_dev); errors++; } /* * Now see if a default mount point is required */ if (STREQ(mp2->m_name, "default")) { if (ISSET(mp2->m_mask, DM_VOLNAME)) { char nbuf[1024]; compute_automount_point(nbuf, dk->d_host, mp2->m_volname); XFREE(mp2->m_name); mp2->m_name = strdup(nbuf); fsi_log("%s:%s has default mount on %s", dk->d_host->h_hostname, dk->d_dev, mp2->m_name); } else { lerror(dk->d_ioloc, "no volname given for %s:%s", dk->d_host->h_hostname, dk->d_dev); errors++; } } /* * Fill in the disk mount point */ if (!errors && mp2 && mp2->m_name) dk->d_mountpt = strdup(mp2->m_name); else dk->d_mountpt = strdup("error"); /* * Analyze the mount tree */ errors += analyze_dkmount_tree(q, 0, dk); /* * Analyze the export tree */ errors += check_exportfs(q, 0); return errors; } static void fixup_required_disk_info(disk_fs *dp) { /* * "fstype" */ if (ISSET(dp->d_mask, DF_FSTYPE)) { if (STREQ(dp->d_fstype, "swap")) { /* * Fixup for a swap device */ if (!ISSET(dp->d_mask, DF_PASSNO)) { dp->d_passno = 0; BITSET(dp->d_mask, DF_PASSNO); } else if (dp->d_freq != 0) { lwarning(dp->d_ioloc, "Pass number for %s:%s is non-zero", dp->d_host->h_hostname, dp->d_dev); } /* * "freq" */ if (!ISSET(dp->d_mask, DF_FREQ)) { dp->d_freq = 0; BITSET(dp->d_mask, DF_FREQ); } else if (dp->d_freq != 0) { lwarning(dp->d_ioloc, "dump frequency for %s:%s is non-zero", dp->d_host->h_hostname, dp->d_dev); } /* * "opts" */ if (!ISSET(dp->d_mask, DF_OPTS)) set_disk_fs(dp, DF_OPTS, strdup("swap")); /* * "mount" */ if (!ISSET(dp->d_mask, DF_MOUNT)) { qelem *q = new_que(); fsi_mount *m = new_mount(); m->m_name = strdup("swap"); m->m_mount = new_que(); ins_que(&m->m_q, q->q_back); dp->d_mount = q; BITSET(dp->d_mask, DF_MOUNT); } else { lerror(dp->d_ioloc, "%s: mount field specified for swap partition", dp->d_host->h_hostname); } } else if (STREQ(dp->d_fstype, "export")) { /* * "passno" */ if (!ISSET(dp->d_mask, DF_PASSNO)) { dp->d_passno = 0; BITSET(dp->d_mask, DF_PASSNO); } else if (dp->d_passno != 0) { lwarning(dp->d_ioloc, "pass number for %s:%s is non-zero", dp->d_host->h_hostname, dp->d_dev); } /* * "freq" */ if (!ISSET(dp->d_mask, DF_FREQ)) { dp->d_freq = 0; BITSET(dp->d_mask, DF_FREQ); } else if (dp->d_freq != 0) { lwarning(dp->d_ioloc, "dump frequency for %s:%s is non-zero", dp->d_host->h_hostname, dp->d_dev); } /* * "opts" */ if (!ISSET(dp->d_mask, DF_OPTS)) set_disk_fs(dp, DF_OPTS, strdup("rw,defaults")); } } } static void fixup_required_mount_info(fsmount *fp, dict_ent *de) { if (!ISSET(fp->f_mask, FM_FROM)) { if (de->de_count != 1) { lerror(fp->f_ioloc, "ambiguous mount: %s is a replicated filesystem", fp->f_volname); } else { dict_data *dd; fsi_mount *mp = 0; dd = AM_FIRST(dict_data, &de->de_q); mp = (fsi_mount *) dd->dd_data; if (!mp) abort(); fp->f_ref = mp; set_fsmount(fp, FM_FROM, mp->m_dk->d_host->h_hostname); fsi_log("set: %s comes from %s", fp->f_volname, fp->f_from); } } if (!ISSET(fp->f_mask, FM_FSTYPE)) { set_fsmount(fp, FM_FSTYPE, strdup("nfs")); fsi_log("set: fstype is %s", fp->f_fstype); } if (!ISSET(fp->f_mask, FM_OPTS)) { set_fsmount(fp, FM_OPTS, strdup("rw,nosuid,grpid,defaults")); fsi_log("set: opts are %s", fp->f_opts); } if (!ISSET(fp->f_mask, FM_LOCALNAME)) { if (fp->f_ref) { set_fsmount(fp, FM_LOCALNAME, strdup(fp->f_volname)); fsi_log("set: localname is %s", fp->f_localname); } else { lerror(fp->f_ioloc, "cannot determine localname since volname %s is not uniquely defined", fp->f_volname); } } } /* * For each disk on a host * analyze the mount information * and fill in any derivable * details. */ static void analyze_drives(host *hp) { qelem *q = hp->h_disk_fs; disk_fs *dp; ITER(dp, disk_fs, q) { int req; fsi_log("Disk %s:", dp->d_dev); dp->d_host = hp; fixup_required_disk_info(dp); req = ~dp->d_mask & DF_REQUIRED; if (req) show_required(dp->d_ioloc, req, dp->d_dev, hp->h_hostname, disk_fs_strings); analyze_dkmounts(dp, dp->d_mount); } } /* * Check that all static mounts make sense and * that the source volumes exist. */ static void analyze_mounts(host *hp) { qelem *q = hp->h_mount; fsmount *fp; int netbootp = 0; ITER(fp, fsmount, q) { char *p; char *nn = strdup(fp->f_volname); int req; dict_ent *de = (dict_ent *) NULL; int found = 0; int matched = 0; if (ISSET(fp->f_mask, FM_DIRECT)) { found = 1; matched = 1; } else do { p = 0; de = find_volname(nn); fsi_log("Mount: %s (trying %s)", fp->f_volname, nn); if (de) { found = 1; /* * Check that the from field is really exporting * the filesystem requested. * LBL: If fake mount, then don't care about * consistency check. */ if (ISSET(fp->f_mask, FM_FROM) && !ISSET(fp->f_mask, FM_DIRECT)) { dict_data *dd; fsi_mount *mp2 = 0; ITER(dd, dict_data, &de->de_q) { fsi_mount *mp = (fsi_mount *) dd->dd_data; if (STREQ(mp->m_dk->d_host->h_hostname, fp->f_from)) { mp2 = mp; break; } } if (mp2) { fp->f_ref = mp2; matched = 1; break; } } else { matched = 1; break; } } p = strrchr(nn, '/'); if (p) *p = 0; } while (de && p); XFREE(nn); if (!found) { lerror(fp->f_ioloc, "volname %s unknown", fp->f_volname); } else if (matched) { fixup_required_mount_info(fp, de); req = ~fp->f_mask & FM_REQUIRED; if (req) { show_required(fp->f_ioloc, req, fp->f_volname, hp->h_hostname, fsmount_strings); } else if (STREQ(fp->f_localname, "/")) { hp->h_netroot = fp; netbootp |= FM_NETROOT; } else if (STREQ(fp->f_localname, "swap")) { hp->h_netswap = fp; netbootp |= FM_NETSWAP; } } else { lerror(fp->f_ioloc, "volname %s not exported from %s", fp->f_volname, fp->f_from ? fp->f_from : "anywhere"); } } if (netbootp && (netbootp != FM_NETBOOT)) lerror(hp->h_ioloc, "network booting requires both root and swap areas"); } void analyze_hosts(qelem *q) { host *hp; show_area_being_processed("analyze hosts", 5); /* * Check all drives */ ITER(hp, host, q) { fsi_log("disks on host %s", hp->h_hostname); show_new("ana-host"); hp->h_hostpath = compute_hostpath(hp->h_hostname); if (hp->h_disk_fs) analyze_drives(hp); } show_area_being_processed("analyze mounts", 5); /* * Check static mounts */ ITER(hp, host, q) { fsi_log("mounts on host %s", hp->h_hostname); show_new("ana-mount"); if (hp->h_mount) analyze_mounts(hp); } } /* * Check an automount request */ static void analyze_automount(automount *ap) { dict_ent *de = find_volname(ap->a_volname); if (de) { ap->a_mounted = de; } else { if (STREQ(ap->a_volname, ap->a_name)) lerror(ap->a_ioloc, "unknown volname %s automounted", ap->a_volname); else lerror(ap->a_ioloc, "unknown volname %s automounted on %s", ap->a_volname, ap->a_name); } } static void analyze_automount_tree(qelem *q, char *pref, int lvl) { automount *ap; ITER(ap, automount, q) { char nname[1024]; if (lvl > 0 || ap->a_mount) if (ap->a_name[1] && strchr(ap->a_name + 1, '/')) lerror(ap->a_ioloc, "not allowed '/' in a directory name"); sprintf(nname, "%s/%s", pref, ap->a_name); XFREE(ap->a_name); ap->a_name = strdup(nname[1] == '/' ? nname + 1 : nname); fsi_log("automount point %s:", ap->a_name); show_new("ana-automount"); if (ap->a_mount) { analyze_automount_tree(ap->a_mount, ap->a_name, lvl + 1); } else if (ap->a_hardwiredfs) { fsi_log("\thardwired from %s to %s", ap->a_volname, ap->a_hardwiredfs); } else if (ap->a_volname) { fsi_log("\tautomount from %s", ap->a_volname); analyze_automount(ap); } else if (ap->a_symlink) { fsi_log("\tsymlink to %s", ap->a_symlink); } else { ap->a_volname = strdup(ap->a_name); fsi_log("\timplicit automount from %s", ap->a_volname); analyze_automount(ap); } } } void analyze_automounts(qelem *q) { auto_tree *tp; show_area_being_processed("analyze automount", 5); /* * q is a list of automounts */ ITER(tp, auto_tree, q) analyze_automount_tree(tp->t_mount, "", 0); }