/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2004 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* Copyright (c) 1984, 1986, 1987, 1988, 1989 AT&T */ /* All Rights Reserved */ /* * University Copyright- Copyright (c) 1982, 1986, 1988 * The Regents of the University of California * All Rights Reserved * * University Acknowledgment- Portions of this document are derived from * software developed by the University of California, Berkeley, and its * contributors. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * df */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include extern char *getenv(); extern char *getcwd(); extern char *realpath(); extern off_t lseek(); /* * Raw name to block device name translation function. * This comes from libadm. */ extern char *getfullblkname(); static void usage(), pheader(); static char *mpath(), *zap_chroot(); static char *pathsuffix(); static char *xmalloc(); static int chroot_stat(); static int bread(); static int abspath(), subpath(); static void show_inode_usage(); static void dfreedev(); static void dfreemnt(); static void print_totals(); static void print_itotals(); static void print_statvfs(); static struct mntlist *mkmntlist(); static struct mnttab *mntdup(), *mdev(char *); static struct mntlist *findmntent(); #define bcopy(f, t, n) memcpy(t, f, n) #define bzero(s, n) memset(s, 0, n) #define bcmp(s, d, n) memcmp(s, d, n) #define index(s, r) strchr(s, r) #define rindex(s, r) strrchr(s, r) #define dbtok(x, b) \ ((b) < (fsblkcnt64_t)1024 ? \ (x) / ((fsblkcnt64_t)1024 / (b)) : (x) * ((b) / (fsblkcnt64_t)1024)) int aflag = 0; /* even the uninteresting ones */ int bflag = 0; /* print only number of kilobytes free */ int eflag = 0; /* print only number of file entries free */ int gflag = 0; /* print entire statvfs structure */ int hflag = 0; /* don't print header */ int iflag = 0; /* information for inodes */ int nflag = 0; /* print VFStype name */ int tflag = 0; /* print totals */ int errflag = 0; int errcode = 0; char *typestr = "ufs"; fsblkcnt64_t t_totalblks, t_avail, t_free, t_used, t_reserved; int t_inodes, t_iused, t_ifree; /* * cached information recording previous chroot history. */ static char *chrootpath; extern int optind; extern char *optarg; union { struct fs iu_fs; char dummy[SBSIZE]; } sb; #define sblock sb.iu_fs /* * This structure is used to chain mntent structures into a list * and to cache stat information for each member of the list. */ struct mntlist { struct mnttab *mntl_mnt; struct mntlist *mntl_next; dev_t mntl_dev; int mntl_devvalid; }; char *subopts [] = { #define A_FLAG 0 "a", #define I_FLAG 1 "i", NULL }; void main(argc, argv) int argc; char *argv[]; { struct mnttab mnt; int opt; char *suboptions, *value; (void) setlocale(LC_ALL, ""); #if !defined(TEXT_DOMAIN) /* Should be defined by cc -D */ #define TEXT_DOMAIN "SYS_TEST" /* Use this only if it weren't */ #endif (void) textdomain(TEXT_DOMAIN); while ((opt = getopt(argc, argv, "beghkno:t")) != EOF) { switch (opt) { case 'b': /* print only number of kilobytes free */ bflag++; break; case 'e': eflag++; /* print only number of file entries free */ iflag++; break; case 'g': gflag++; break; case 'n': nflag++; break; case 'k': break; case 'h': hflag++; break; case 'o': /* * ufs specific options. */ suboptions = optarg; while (*suboptions != '\0') { switch (getsubopt(&suboptions, subopts, &value)) { case I_FLAG: /* information for inodes */ iflag++; break; default: usage(); } } break; case 't': /* print totals */ tflag++; break; case 'V': /* Print command line */ { char *opt_text; int opt_count; (void) fprintf(stdout, "df -F ufs "); for (opt_count = 1; opt_count < argc; opt_count++) { opt_text = argv[opt_count]; if (opt_text) (void) fprintf(stdout, " %s ", opt_text); } (void) fprintf(stdout, "\n"); } break; case '?': errflag++; } } if (errflag) usage(); if (gflag && iflag) { printf(gettext("df: '-g' and '-o i' are mutually exclusive\n")); exit(1); } if (bflag || eflag) tflag = 0; /* * Cache CHROOT information for later use; assume that $CHROOT matches * the cumulative arguments given to chroot calls. */ chrootpath = getenv("CHROOT"); if (chrootpath != NULL && strcmp(chrootpath, "/") == 0) chrootpath = NULL; if (argc <= optind) { /* * Take this path when "/usr/lib/fs/ufs/df" is specified, and * there are no mountpoints specified. * E.g., these command lines take us down this path * /usr/lib/fs/ufs/df -o i * /usr/lib/fs/ufs/df */ register FILE *mtabp; if ((mtabp = fopen(MNTTAB, "r")) == NULL) { (void) fprintf(stderr, "df: "); perror(MNTTAB); exit(1); } pheader(); while (getmntent(mtabp, &mnt) == 0) { if (strcmp(typestr, mnt.mnt_fstype) != 0) { continue; } dfreemnt(mnt.mnt_mountp, &mnt); } if (tflag) if (iflag) print_itotals(); else print_totals(); (void) fclose(mtabp); } else { int i; struct mntlist *mntl; struct stat64 *argstat; char **devnames; char *cp; /* * Obtain stat64 information for each argument before * constructing the list of mounted file systems. This * ordering forces the automounter to establish any * mounts required to access the arguments, so that the * corresponding mount table entries will exist when * we look for them. */ argv++; argc--; argstat = (struct stat64 *)xmalloc(argc * sizeof (*argstat)); devnames = (char **)xmalloc(argc * sizeof (char *)); for (i = 0; i < argc; i++) { /* * Given a raw device name, get the block device name */ cp = getfullblkname(argv[i]); if (cp == NULL || *cp == '\0') { if (cp != NULL) free(cp); cp = strdup(argv[i]); if (cp == NULL) { int j; fprintf(stderr, gettext( "df: memory allocation failure\n")); for (j = 0; j < i; j++) free(devnames[j]); free(devnames); free(argstat); exit(1); } } if (stat64(cp, &argstat[i]) < 0) { errcode = errno; /* * Mark as no longer interesting. */ argv[i] = NULL; devnames[i] = NULL; free(cp); } else { devnames[i] = cp; } } pheader(); aflag++; /* * Construct the list of mounted file systems. */ mntl = mkmntlist(); /* * Iterate through the argument list, reporting on each one. */ for (i = 0; i < argc; i++) { register struct mntlist *mlp; int isblk; /* * Skip if we've already determined that we can't * process it. */ if (argv[i] == NULL) continue; /* * If the argument names a device, report on the file * system associated with the device rather than on * the one containing the device's directory entry */ cp = devnames[i]; if ((isblk = (argstat[i].st_mode&S_IFMT) == S_IFBLK) || (argstat[i].st_mode & S_IFMT) == S_IFCHR) { if (isblk && strcmp(mpath(cp), "") != 0) { struct mnttab *mp = mdev(cp); dfreemnt(mp->mnt_mountp, mp); } else { dfreedev(cp); } free(cp); devnames[i] = NULL; continue; } /* * Get this argument's corresponding mount table * entry. */ mlp = findmntent(cp, &argstat[i], mntl); free(cp); devnames[i] = NULL; if (mlp == NULL) { (void) fprintf(stderr, gettext("Could not find mount point for %s\n"), argv[i]); continue; } dfreemnt(mlp->mntl_mnt->mnt_mountp, mlp->mntl_mnt); } free(devnames); free(argstat); } exit(0); /*NOTREACHED*/ } void pheader() { if (hflag) return; if (nflag) (void) printf(gettext("VFStype name - ufs\n")); if (iflag) { if (eflag) /* * TRANSLATION_NOTE * Following string is used as a table header. * Translated items should start at the same * columns as the original items. */ (void) printf(gettext( "Filesystem ifree\n")); else { /* * TRANSLATION_NOTE * Following string is used as a table header. * Translated items should start at the same * columns as the original items. */ (void) printf(gettext( "Filesystem iused ifree %%iused Mounted on\n")); } } else { if (gflag) /* * TRANSLATION_NOTE * Following string is used as a table header. * Translated items should start at the same * columns as the original items. */ (void) printf(gettext( "Filesystem f_type f_fsize f_bfree f_bavail f_files f_ffree " "f_fsid f_flag f_fstr\n")); else if (bflag) /* * TRANSLATION_NOTE * Following string is used as a table header. * Translated items should start at the same * columns as the original items. */ (void) printf(gettext( "Filesystem avail\n")); else { /* * TRANSLATION_NOTE * Following string is used as a table header. * Translated items should start at the same * columns as the original items. */ (void) printf(gettext( "Filesystem kbytes used avail capacity Mounted on\n")); } } } /* * Report on a block or character special device. Assumed not to be * mounted. N.B. checks for a valid UFS superblock. */ void dfreedev(file) char *file; { fsblkcnt64_t totalblks, availblks, avail, free, used; int fi; fi = open64(file, 0); if (fi < 0) { (void) fprintf(stderr, "df: "); perror(file); return; } if (bread(file, fi, SBLOCK, (char *)&sblock, SBSIZE) == 0) { (void) close(fi); return; } if ((sblock.fs_magic != FS_MAGIC) && (sblock.fs_magic != MTB_UFS_MAGIC)) { (void) fprintf(stderr, gettext( "df: %s: not a ufs file system\n"), file); (void) close(fi); return; } if (sblock.fs_magic == MTB_UFS_MAGIC && (sblock.fs_version > MTB_UFS_VERSION_1 || sblock.fs_version < MTB_UFS_VERSION_MIN)) { (void) fprintf(stderr, gettext( "df: %s: unrecognized version of UFS: %d\n"), file, sblock.fs_version); (void) close(fi); return; } (void) printf("%-20.20s", file); if (iflag) { if (eflag) { (void) printf("%8ld", sblock.fs_cstotal.cs_nifree); } else { show_inode_usage( (fsfilcnt64_t)sblock.fs_ncg * (fsfilcnt64_t)sblock.fs_ipg, (fsfilcnt64_t)sblock.fs_cstotal.cs_nifree); } } else { totalblks = (fsblkcnt64_t)sblock.fs_dsize; free = (fsblkcnt64_t)sblock.fs_cstotal.cs_nbfree * (fsblkcnt64_t)sblock.fs_frag + (fsblkcnt64_t)sblock.fs_cstotal.cs_nffree; used = totalblks - free; availblks = totalblks / (fsblkcnt64_t)100 * ((fsblkcnt64_t)100 - (fsblkcnt64_t)sblock.fs_minfree); avail = availblks > used ? availblks - used : (fsblkcnt64_t)0; if (bflag) { (void) printf("%8lld\n", dbtok(avail, (fsblkcnt64_t)sblock.fs_fsize)); } else { (void) printf(" %7lld %7lld %7lld", dbtok(totalblks, (fsblkcnt64_t)sblock.fs_fsize), dbtok(used, (fsblkcnt64_t)sblock.fs_fsize), dbtok(avail, (fsblkcnt64_t)sblock.fs_fsize)); (void) printf("%6.0f%%", availblks == 0 ? 0.0 : (double)used / (double)availblks * 100.0); (void) printf(" "); } if (tflag) { t_totalblks += dbtok(totalblks, (fsblkcnt64_t)sblock.fs_fsize); t_used += dbtok(used, (fsblkcnt64_t)sblock.fs_fsize); t_avail += dbtok(avail, (fsblkcnt64_t)sblock.fs_fsize); t_free += free; } } if ((!bflag) && (!eflag)) (void) printf(" %s\n", mpath(file)); else if (eflag) (void) printf("\n"); (void) close(fi); } void dfreemnt(file, mnt) char *file; struct mnttab *mnt; { struct statvfs64 fs; if (statvfs64(file, &fs) < 0 && chroot_stat(file, statvfs64, (char *)&fs, &file) < 0) { (void) fprintf(stderr, "df: "); perror(file); return; } if (!aflag && fs.f_blocks == 0) { return; } if (!isatty(fileno(stdout))) { (void) printf("%s", mnt->mnt_special); } else { if (strlen(mnt->mnt_special) > (size_t)20) { (void) printf("%s\n", mnt->mnt_special); (void) printf(" "); } else { (void) printf("%-20.20s", mnt->mnt_special); } } if (iflag) { if (eflag) { (void) printf("%8lld", fs.f_ffree); } else { show_inode_usage(fs.f_files, fs.f_ffree); } } else { if (gflag) { print_statvfs(&fs); } else { fsblkcnt64_t totalblks, avail, free, used, reserved; totalblks = fs.f_blocks; free = fs.f_bfree; used = totalblks - free; avail = fs.f_bavail; reserved = free - avail; if ((long long)avail < 0) avail = 0; if (bflag) { (void) printf("%8lld\n", dbtok(avail, (fsblkcnt64_t)fs.f_frsize)); } else { (void) printf(" %7lld %7lld %7lld", dbtok(totalblks, (fsblkcnt64_t)fs.f_frsize), dbtok(used, (fsblkcnt64_t)fs.f_frsize), dbtok(avail, (fsblkcnt64_t)fs.f_frsize)); totalblks -= reserved; (void) printf("%6.0f%%", totalblks == 0 ? 0.0 : (double)used / (double)totalblks * 100.0); (void) printf(" "); if (tflag) { t_totalblks += dbtok(totalblks + reserved, (fsblkcnt64_t)fs.f_bsize); t_reserved += reserved; t_used += dbtok(used, (fsblkcnt64_t)fs.f_frsize); t_avail += dbtok(avail, (fsblkcnt64_t)fs.f_frsize); t_free += free; } } } } if ((!bflag) && (!eflag) && (!gflag)) (void) printf(" %s\n", mnt->mnt_mountp); else if (eflag) (void) printf("\n"); } static void show_inode_usage(fsfilcnt64_t total, fsfilcnt64_t free) { fsfilcnt64_t used = total - free; int missing_info = ((long long)total == (long long)-1 || (long long)free == (long long)-1); if (missing_info) (void) printf("%8s", "*"); else (void) printf("%8lld", used); if ((long long)free == (long long)-1) (void) printf("%8s", "*"); else (void) printf(" %7lld", free); if (missing_info) (void) printf("%6s ", "*"); else (void) printf("%6.0f%% ", (double)used / (double)total * 100.0); } /* * Return the suffix of path obtained by stripping off the prefix * that is the value of the CHROOT environment variable. If this * value isn't obtainable or if it's not a prefix of path, return NULL. */ static char * zap_chroot(path) char *path; { return (pathsuffix(path, chrootpath)); } /* * Stat/statfs a file after stripping off leading directory to which we are * chroot'd. Used to find the TFS mount that applies to the current * activated NSE environment. */ static int chroot_stat(dir, statfunc, statp, dirp) char *dir; int (*statfunc)(); char *statp; char **dirp; { if ((dir = zap_chroot(dir)) == NULL) return (-1); if (dirp) *dirp = dir; return (*statfunc)(dir, statp); } /* * Given a name like /dev/dsk/c1d0s2, returns the mounted path, like /usr. */ char * mpath(char *file) { struct mnttab mnt; FILE *mnttab; struct stat64 device_stat, mount_stat; char *mname; mnttab = fopen(MNTTAB, "r"); if (mnttab == NULL) { return (""); } mname = ""; while ((getmntent(mnttab, &mnt)) == 0) { if (strcmp(mnt.mnt_fstype, MNTTYPE_UFS) != 0) { continue; } if (strcmp(file, mnt.mnt_special) == 0) { if (stat64(mnt.mnt_mountp, &mount_stat) != 0) continue; if (stat64(mnt.mnt_special, &device_stat) != 0) continue; if (device_stat.st_rdev == mount_stat.st_dev) { mname = mnt.mnt_mountp; break; } } } fclose(mnttab); return (mname); } /* * Given a special device, return mnttab entry */ struct mnttab * mdev(char *spec) { FILE *mntp; struct mnttab mnt; if ((mntp = fopen(MNTTAB, "r")) == 0) { (void) fprintf(stderr, "df: "); perror(MNTTAB); exit(1); } while (getmntent(mntp, &mnt) == 0) { if (strcmp(spec, mnt.mnt_special) == 0) { (void) fclose(mntp); return (mntdup(&mnt)); } } (void) fclose(mntp); (void) fprintf(stderr, "df : couldn't find mnttab entry for %s", spec); exit(1); } /* * Find the entry in mlist that corresponds to the file named by path * (i.e., that names a mount table entry for the file system in which * path lies). The pstat argument must point to stat information for * path. * * Return the entry or NULL if there's no match. * * As it becomes necessary to obtain stat information about previously * unexamined mlist entries, gather the information and cache it with the * entries. * * The routine's strategy is to convert path into its canonical, symlink-free * representation canon (which will require accessing the file systems on the * branch from the root to path and thus may cause the routine to hang if any * of them are inaccessible) and to use it to search for a mount point whose * name is a substring of canon and whose corresponding device matches that of * canon. This technique avoids accessing unnecessary file system resources * and thus prevents the program from hanging on inaccessible resources unless * those resources are necessary for accessing path. */ static struct mntlist * findmntent(path, pstat, mlist) char *path; struct stat64 *pstat; struct mntlist *mlist; { static char cwd[MAXPATHLEN]; char canon[MAXPATHLEN]; char scratch[MAXPATHLEN]; register struct mntlist *mlp; /* * If path is relative and we haven't already determined the current * working directory, do so now. Calculating the working directory * here lets us do the work once, instead of (potentially) repeatedly * in realpath(). */ if (*path != '/' && cwd[0] == '\0') { if (getcwd(cwd, MAXPATHLEN) == NULL) { cwd[0] = '\0'; return (NULL); } } /* * Find an absolute pathname in the native file system name space that * corresponds to path, stuffing it into canon. * * If CHROOT is set in the environment, assume that chroot($CHROOT) * (or an equivalent series of calls) was executed and convert the * path to the equivalent name in the native file system's name space. * Doing so allows direct comparison with the names in mtab entires, * which are assumed to be recorded relative to the native name space. */ if (abspath(cwd, path, scratch) < 0) return (NULL); if (strcmp(scratch, "/") == 0 && chrootpath != NULL) { /* * Force canon to be in canonical form; if the result from * abspath was "/" and chrootpath isn't the null string, we * must strip off a trailing slash. */ scratch[0] = '\0'; } (void) sprintf(canon, "%s%s", chrootpath ? chrootpath : "", scratch); again: for (mlp = mlist; mlp; mlp = mlp->mntl_next) { struct mnttab *mnt = mlp->mntl_mnt; /* * Ignore uninteresting mounts. */ if (strcmp(mnt->mnt_fstype, typestr) != 0) continue; /* * The mount entry covers some prefix of the file. * See whether it's the entry for the file system * containing the file by comparing device ids. */ if (mlp->mntl_dev == NODEV) { struct stat64 fs_sb; if (stat64(mnt->mnt_mountp, &fs_sb) < 0 && chroot_stat(mnt->mnt_mountp, stat64, (char *)&fs_sb, (char **)NULL) < 0) { continue; } mlp->mntl_dev = fs_sb.st_dev; } if (pstat->st_dev == mlp->mntl_dev) return (mlp); } return (NULL); } /* * Convert the path given in raw to canonical, absolute, symlink-free * form, storing the result in the buffer named by canon, which must be * at least MAXPATHLEN bytes long. "wd" contains the current working * directory; accepting this value as an argument lets our caller cache * the value, so that realpath (called from this routine) doesn't have * to recalculate it each time it's given a relative pathname. * * Return 0 on success, -1 on failure. */ static int abspath(wd, raw, canon) char *wd; register char *raw; char *canon; { char absbuf[MAXPATHLEN]; /* * Preliminary sanity check. */ if (wd == NULL || raw == NULL || canon == NULL) return (-1); /* * If the path is relative, convert it to absolute form, * using wd if it's been supplied. */ if (raw[0] != '/') { register char *limit = absbuf + sizeof (absbuf); register char *d; /* Fill in working directory. */ if (strlcpy(absbuf, wd, sizeof (absbuf)) >= sizeof (absbuf)) return (-1); /* Add separating slash. */ d = absbuf + strlen(absbuf); if (d < limit) *d++ = '/'; /* Glue on the relative part of the path. */ while (d < limit && (*d++ = *raw++)) continue; raw = absbuf; } /* * Call realpath to canonicalize and resolve symlinks. */ return (realpath(raw, canon) == NULL ? -1 : 0); } /* * Return a pointer to the trailing suffix of full that follows the prefix * given by pref. If pref isn't a prefix of full, return NULL. Apply * pathname semantics to the prefix test, so that pref must match at a * component boundary. */ static char * pathsuffix(full, pref) register char *full; register char *pref; { register int preflen; if (full == NULL || pref == NULL) return (NULL); preflen = strlen(pref); if (strncmp(pref, full, preflen) != 0) return (NULL); /* * pref is a substring of full. To be a subpath, it cannot cover a * partial component of full. The last clause of the test handles the * special case of the root. */ if (full[preflen] != '\0' && full[preflen] != '/' && preflen > 1) return (NULL); if (preflen == 1 && full[0] == '/') return (full); else return (full + preflen); } /* * Return zero iff the path named by sub is a leading subpath * of the path named by full. * * Treat null paths as matching nothing. */ static int subpath(full, sub) register char *full; register char *sub; { return (pathsuffix(full, sub) == NULL); } offset_t llseek(); int bread(file, fi, bno, buf, cnt) char *file; int fi; daddr_t bno; char *buf; int cnt; { register int n; (void) llseek(fi, (offset_t)bno * DEV_BSIZE, 0); if ((n = read(fi, buf, cnt)) < 0) { /* probably a dismounted disk if errno == EIO */ if (errno != EIO) { (void) fprintf(stderr, gettext("df: read error on ")); perror(file); (void) fprintf(stderr, "bno = %ld\n", bno); } else { (void) fprintf(stderr, gettext( "df: premature EOF on %s\n"), file); (void) fprintf(stderr, "bno = %ld expected = %d count = %d\n", bno, cnt, n); } return (0); } return (1); } char * xmalloc(size) unsigned int size; { register char *ret; char *malloc(); if ((ret = (char *)malloc(size)) == NULL) { (void) fprintf(stderr, gettext("umount: ran out of memory!\n")); exit(1); } return (ret); } struct mnttab * mntdup(mnt) register struct mnttab *mnt; { register struct mnttab *new; new = (struct mnttab *)xmalloc(sizeof (*new)); new->mnt_special = (char *)xmalloc((unsigned)(strlen(mnt->mnt_special) + 1)); (void) strcpy(new->mnt_special, mnt->mnt_special); new->mnt_mountp = (char *)xmalloc((unsigned)(strlen(mnt->mnt_mountp) + 1)); (void) strcpy(new->mnt_mountp, mnt->mnt_mountp); new->mnt_fstype = (char *)xmalloc((unsigned)(strlen(mnt->mnt_fstype) + 1)); (void) strcpy(new->mnt_fstype, mnt->mnt_fstype); if (mnt->mnt_mntopts != NULL) { new->mnt_mntopts = (char *)xmalloc((unsigned)(strlen(mnt->mnt_mntopts) + 1)); (void) strcpy(new->mnt_mntopts, mnt->mnt_mntopts); } else { new->mnt_mntopts = NULL; } #ifdef never new->mnt_freq = mnt->mnt_freq; new->mnt_passno = mnt->mnt_passno; #endif /* never */ return (new); } void usage() { (void) fprintf(stderr, gettext( "ufs usage: df [generic options] [-o i] [directory | special]\n")); exit(1); } struct mntlist * mkmntlist() { FILE *mounted; struct mntlist *mntl; struct mntlist *mntst = NULL; struct extmnttab mnt; if ((mounted = fopen(MNTTAB, "r")) == NULL) { (void) fprintf(stderr, "df : "); perror(MNTTAB); exit(1); } resetmnttab(mounted); while (getextmntent(mounted, &mnt, sizeof (struct extmnttab)) == NULL) { mntl = (struct mntlist *)xmalloc(sizeof (*mntl)); mntl->mntl_mnt = mntdup((struct mnttab *)(&mnt)); mntl->mntl_next = mntst; mntl->mntl_devvalid = 1; mntl->mntl_dev = makedev(mnt.mnt_major, mnt.mnt_minor); mntst = mntl; } (void) fclose(mounted); return (mntst); } void print_statvfs(fs) struct statvfs64 *fs; { int i; for (i = 0; i < FSTYPSZ; i++) (void) printf("%c", fs->f_basetype[i]); (void) printf(" %7d %7lld %7lld", fs->f_frsize, fs->f_blocks, fs->f_bavail); (void) printf(" %7lld %7lld %7d", fs->f_files, fs->f_ffree, fs->f_fsid); (void) printf(" 0x%x ", fs->f_flag); for (i = 0; i < 14; i++) (void) printf("%c", (fs->f_fstr[i] == '\0') ? ' ' : fs->f_fstr[i]); printf("\n"); } void print_totals() { /* * TRANSLATION_NOTE * Following string is used as a table header. * Translated items should start at the same * columns as the original items. */ (void) printf(gettext("Totals %8lld %7lld %7lld"), t_totalblks, t_used, t_avail); (void) printf("%6.0f%%\n", (t_totalblks - t_reserved) == (fsblkcnt64_t)0 ? 0.0 : (double)t_used / (double)(t_totalblks - t_reserved) * 100.0); } void print_itotals() { /* * TRANSLATION_NOTE * Following string is used as a table header. * Translated items should start at the same * columns as the original items. */ (void) printf(gettext("Totals %8d %7d%6.0f%%\n"), t_iused, t_ifree, t_inodes == 0 ? 0.0 : (double)t_iused / (double)t_inodes * 100.0); }