/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (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 (c) 1984, 1986, 1987, 1988, 1989 AT&T */ /* All Rights Reserved */ /* * Copyright 2010 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "fslib.h" extern char *default_fstype(char *); /* * General notice: * String pointers in this code may point to statically allocated memory * or dynamically allocated memory. Furthermore, a dynamically allocated * string may be pointed to by more than one pointer. This does not pose * a problem because malloc'ed memory is never free'd (so we don't need * to remember which pointers point to malloc'ed memory). */ /* * TRANSLATION_NOTE * Only strings passed as arguments to the TRANSLATE macro need to * be translated. */ #ifndef MNTTYPE_LOFS #define MNTTYPE_LOFS "lofs" #endif #define EQ(s1, s2) (strcmp(s1, s2) == 0) #define NEW(type) xmalloc(sizeof (type)) #define CLEAR(var) (void) memset(&(var), 0, sizeof (var)) #define MAX(a, b) ((a) > (b) ? (a) : (b)) #define MAX3(a, b, c) MAX(a, MAX(b, c)) #define TRANSLATE(s) new_string(gettext(s)) #define MAX_OPTIONS 36 #define N_FSTYPES 20 #define MOUNT_TABLE_ENTRIES 40 /* initial allocation */ #define MSGBUF_SIZE 1024 #define LINEBUF_SIZE 256 /* either input or output lines */ #define BLOCK_SIZE 512 /* when reporting in terms of blocks */ #define DEVNM_CMD "devnm" #define FS_LIBPATH "/usr/lib/fs/" #define MOUNT_TAB "/etc/mnttab" #define VFS_TAB "/etc/vfstab" #define REMOTE_FS "/etc/dfs/fstypes" #define NUL '\0' #define FALSE 0 #define TRUE 1 /* * Formatting constants */ #define IBCS2_FILESYSTEM_WIDTH 15 /* Truncate to match ISC/SCO */ #define IBCS2_MOUNT_POINT_WIDTH 10 /* Truncate to match ISC/SCO */ #define FILESYSTEM_WIDTH 20 #define MOUNT_POINT_WIDTH 19 #define SPECIAL_DEVICE_WIDTH 18 #define FSTYPE_WIDTH 8 #define BLOCK_WIDTH 8 #define NFILES_WIDTH 8 #ifdef XPG4 #define KBYTE_WIDTH 11 #define AVAILABLE_WIDTH 10 #else #define KBYTE_WIDTH 7 #define AVAILABLE_WIDTH 6 #endif #define SCALED_WIDTH 6 #define CAPACITY_WIDTH 9 #define BSIZE_WIDTH 6 #define FRAGSIZE_WIDTH 7 #define FSID_WIDTH 7 #define FLAG_WIDTH 8 #define NAMELEN_WIDTH 7 #define MNT_SPEC_WIDTH MOUNT_POINT_WIDTH + SPECIAL_DEVICE_WIDTH + 2 /* * Flags for the errmsg() function */ #define ERR_NOFLAGS 0x0 #define ERR_NONAME 0x1 /* don't include the program name */ /* as a prefix */ #define ERR_FATAL 0x2 /* call exit after printing the */ /* message */ #define ERR_PERROR 0x4 /* append an errno explanation to */ /* the message */ #define ERR_USAGE 0x8 /* print the usage line after the */ /* message */ #define NUMBER_WIDTH 40 /* * A numbuf_t is used when converting a number to a string representation */ typedef char numbuf_t[ NUMBER_WIDTH ]; /* * We use bool_int instead of int to make clear which variables are * supposed to be boolean */ typedef int bool_int; struct mtab_entry { bool_int mte_dev_is_valid; dev_t mte_dev; bool_int mte_ignore; /* the "ignore" option was set */ struct extmnttab *mte_mount; }; struct df_request { bool_int dfr_valid; char *dfr_cmd_arg; /* what the user specified */ struct mtab_entry *dfr_mte; char *dfr_fstype; int dfr_index; /* to make qsort stable */ }; #define DFR_MOUNT_POINT(dfrp) (dfrp)->dfr_mte->mte_mount->mnt_mountp #define DFR_SPECIAL(dfrp) (dfrp)->dfr_mte->mte_mount->mnt_special #define DFR_FSTYPE(dfrp) (dfrp)->dfr_mte->mte_mount->mnt_fstype #define DFR_ISMOUNTEDFS(dfrp) ((dfrp)->dfr_mte != NULL) #define DFRP(p) ((struct df_request *)(p)) typedef void (*output_func)(struct df_request *, struct statvfs64 *); struct df_output { output_func dfo_func; /* function that will do the output */ int dfo_flags; }; /* * Output flags */ #define DFO_NOFLAGS 0x0 #define DFO_HEADER 0x1 /* output preceded by header */ #define DFO_STATVFS 0x2 /* must do a statvfs64(2) */ static char *program_name; static char df_options[MAX_OPTIONS] = "-"; static size_t df_options_len = 1; static char *o_option_arg; /* arg to the -o option */ static char *FSType; static char *remote_fstypes[N_FSTYPES+1]; /* allocate an extra one */ /* to use as a terminator */ /* * The following three variables support an in-memory copy of the mount table * to speedup searches. */ static struct mtab_entry *mount_table; /* array of mtab_entry's */ static size_t mount_table_entries; static size_t mount_table_allocated_entries; static bool_int F_option; static bool_int V_option; static bool_int P_option; /* Added for XCU4 compliance */ static bool_int Z_option; static bool_int v_option; #ifdef _iBCS2 char *sysv3_set; #endif /* _iBCS2 */ static bool_int a_option; static bool_int b_option; static bool_int e_option; static bool_int g_option; static bool_int h_option; static bool_int k_option; static bool_int l_option; static bool_int n_option; static bool_int t_option; static bool_int o_option; static bool_int tty_output; static bool_int use_scaling; static int scale; static void usage(void); static void do_devnm(int, char **); static void do_df(int, char **) __NORETURN; static void parse_options(int, char **); static char *basename(char *); static libzfs_handle_t *(*_libzfs_init)(boolean_t); static zfs_handle_t *(*_zfs_open)(libzfs_handle_t *, const char *, int); static void (*_zfs_close)(zfs_handle_t *); static uint64_t (*_zfs_prop_get_int)(zfs_handle_t *, zfs_prop_t); static libzfs_handle_t *g_zfs; /* * Dynamically check for libzfs, in case the user hasn't installed the SUNWzfs * packages. A basic utility such as df shouldn't depend on optional * filesystems. */ static boolean_t load_libzfs(void) { void *hdl; if (_libzfs_init != NULL) return (g_zfs != NULL); if ((hdl = dlopen("libzfs.so", RTLD_LAZY)) != NULL) { _libzfs_init = (libzfs_handle_t *(*)(boolean_t))dlsym(hdl, "libzfs_init"); _zfs_open = (zfs_handle_t *(*)())dlsym(hdl, "zfs_open"); _zfs_close = (void (*)())dlsym(hdl, "zfs_close"); _zfs_prop_get_int = (uint64_t (*)()) dlsym(hdl, "zfs_prop_get_int"); if (_libzfs_init != NULL) { assert(_zfs_open != NULL); assert(_zfs_close != NULL); assert(_zfs_prop_get_int != NULL); g_zfs = _libzfs_init(B_FALSE); } } return (g_zfs != NULL); } int main(int argc, char *argv[]) { (void) setlocale(LC_ALL, ""); #if !defined(TEXT_DOMAIN) /* Should be defined by cc -D */ #define TEXT_DOMAIN "SYS_TEST" #endif (void) textdomain(TEXT_DOMAIN); program_name = basename(argv[0]); #ifdef _iBCS2 sysv3_set = getenv("SYSV3"); #endif /* _iBCS2 */ if (EQ(program_name, DEVNM_CMD)) do_devnm(argc, argv); parse_options(argc, argv); /* * The k_option implies SunOS 4.x compatibility: when the special * device name is too long the line will be split except when the * output has been redirected. * This is also valid for the -h option. */ if (use_scaling || k_option || P_option || v_option) tty_output = isatty(1); do_df(argc - optind, &argv[optind]); /* NOTREACHED */ } /* * Prints an error message to stderr. */ /* VARARGS2 */ static void errmsg(int flags, char *fmt, ...) { char buf[MSGBUF_SIZE]; va_list ap; int cc; int offset; if (flags & ERR_NONAME) offset = 0; else offset = sprintf(buf, "%s: ", program_name); va_start(ap, fmt); cc = vsprintf(&buf[offset], gettext(fmt), ap); offset += cc; va_end(ap); if (flags & ERR_PERROR) { if (buf[offset-1] != ' ') (void) strcat(buf, " "); (void) strcat(buf, strerror(errno)); } (void) fprintf(stderr, "%s\n", buf); if (flags & ERR_USAGE) usage(); if (flags & ERR_FATAL) exit(1); } static void usage(void) { #ifdef XPG4 errmsg(ERR_NONAME, "Usage: %s [-F FSType] [-abeghklntPVZ] [-o FSType-specific_options]" " [directory | block_device | resource]", program_name); #else errmsg(ERR_NONAME, "Usage: %s [-F FSType] [-abeghklntVvZ] [-o FSType-specific_options]" " [directory | block_device | resource]", program_name); #endif exit(1); /* NOTREACHED */ } static char * new_string(char *s) { char *p = NULL; if (s) { p = strdup(s); if (p) return (p); errmsg(ERR_FATAL, "out of memory"); /* NOTREACHED */ } return (p); } /* * Allocate memory using malloc but terminate if the allocation fails */ static void * xmalloc(size_t size) { void *p = malloc(size); if (p) return (p); errmsg(ERR_FATAL, "out of memory"); /* NOTREACHED */ return (NULL); } /* * Allocate memory using realloc but terminate if the allocation fails */ static void * xrealloc(void *ptr, size_t size) { void *p = realloc(ptr, size); if (p) return (p); errmsg(ERR_FATAL, "out of memory"); /* NOTREACHED */ return (NULL); } /* * fopen the specified file for reading but terminate if the fopen fails */ static FILE * xfopen(char *file) { FILE *fp = fopen(file, "r"); if (fp == NULL) errmsg(ERR_FATAL + ERR_PERROR, "failed to open %s:", file); return (fp); } /* * Read remote file system types from REMOTE_FS into the * remote_fstypes array. */ static void init_remote_fs(void) { FILE *fp; char line_buf[LINEBUF_SIZE]; size_t fstype_index = 0; if ((fp = fopen(REMOTE_FS, "r")) == NULL) { errmsg(ERR_NOFLAGS, "Warning: can't open %s, ignored", REMOTE_FS); return; } while (fgets(line_buf, sizeof (line_buf), fp) != NULL) { char buf[LINEBUF_SIZE]; (void) sscanf(line_buf, "%s", buf); remote_fstypes[fstype_index++] = new_string(buf); if (fstype_index == N_FSTYPES) break; } (void) fclose(fp); } /* * Returns TRUE if fstype is a remote file system type; * otherwise, returns FALSE. */ static int is_remote_fs(char *fstype) { char **p; static bool_int remote_fs_initialized; if (! remote_fs_initialized) { init_remote_fs(); remote_fs_initialized = TRUE; } for (p = remote_fstypes; *p; p++) if (EQ(fstype, *p)) return (TRUE); return (FALSE); } static char * basename(char *s) { char *p = strrchr(s, '/'); return (p ? p+1 : s); } /* * Create a new "struct extmnttab" and make sure that its fields point * to malloc'ed memory */ static struct extmnttab * mntdup(struct extmnttab *old) { struct extmnttab *new = NEW(struct extmnttab); new->mnt_special = new_string(old->mnt_special); new->mnt_mountp = new_string(old->mnt_mountp); new->mnt_fstype = new_string(old->mnt_fstype); new->mnt_mntopts = new_string(old->mnt_mntopts); new->mnt_time = new_string(old->mnt_time); new->mnt_major = old->mnt_major; new->mnt_minor = old->mnt_minor; return (new); } static void mtab_error(char *mtab_file, int status) { if (status == MNT_TOOLONG) errmsg(ERR_NOFLAGS, "a line in %s exceeds %d characters", mtab_file, MNT_LINE_MAX); else if (status == MNT_TOOMANY) errmsg(ERR_NOFLAGS, "a line in %s has too many fields", mtab_file); else if (status == MNT_TOOFEW) errmsg(ERR_NOFLAGS, "a line in %s has too few fields", mtab_file); else errmsg(ERR_NOFLAGS, "error while reading %s: %d", mtab_file, status); exit(1); /* NOTREACHED */ } /* * Read the mount table from the specified file. * We keep the table in memory for faster lookups. */ static void mtab_read_file(void) { char *mtab_file = MOUNT_TAB; FILE *fp; struct extmnttab mtab; int status; fp = xfopen(mtab_file); resetmnttab(fp); mount_table_allocated_entries = MOUNT_TABLE_ENTRIES; mount_table_entries = 0; mount_table = xmalloc( mount_table_allocated_entries * sizeof (struct mtab_entry)); while ((status = getextmntent(fp, &mtab, sizeof (struct extmnttab))) == 0) { struct mtab_entry *mtep; if (mount_table_entries == mount_table_allocated_entries) { mount_table_allocated_entries += MOUNT_TABLE_ENTRIES; mount_table = xrealloc(mount_table, mount_table_allocated_entries * sizeof (struct mtab_entry)); } mtep = &mount_table[mount_table_entries++]; mtep->mte_mount = mntdup(&mtab); mtep->mte_dev_is_valid = FALSE; mtep->mte_ignore = (hasmntopt((struct mnttab *)&mtab, MNTOPT_IGNORE) != NULL); } (void) fclose(fp); if (status == -1) /* reached EOF */ return; mtab_error(mtab_file, status); /* NOTREACHED */ } /* * We use this macro when we want to record the option for the purpose of * passing it to the FS-specific df */ #define SET_OPTION(opt) opt##_option = TRUE, \ df_options[df_options_len++] = arg static void parse_options(int argc, char *argv[]) { int arg; opterr = 0; /* getopt shouldn't complain about unknown options */ #ifdef XPG4 while ((arg = getopt(argc, argv, "F:o:abehkVtgnlPZ")) != EOF) { #else while ((arg = getopt(argc, argv, "F:o:abehkVtgnlvZ")) != EOF) { #endif if (arg == 'F') { if (F_option) errmsg(ERR_FATAL + ERR_USAGE, "more than one FSType specified"); F_option = 1; FSType = optarg; } else if (arg == 'V' && ! V_option) { V_option = TRUE; } else if (arg == 'v' && ! v_option) { v_option = TRUE; #ifdef XPG4 } else if (arg == 'P' && ! P_option) { SET_OPTION(P); #endif } else if (arg == 'a' && ! a_option) { SET_OPTION(a); } else if (arg == 'b' && ! b_option) { SET_OPTION(b); } else if (arg == 'e' && ! e_option) { SET_OPTION(e); } else if (arg == 'g' && ! g_option) { SET_OPTION(g); } else if (arg == 'h') { use_scaling = TRUE; scale = 1024; } else if (arg == 'k' && ! k_option) { SET_OPTION(k); } else if (arg == 'l' && ! l_option) { SET_OPTION(l); } else if (arg == 'n' && ! n_option) { SET_OPTION(n); } else if (arg == 't' && ! t_option) { SET_OPTION(t); } else if (arg == 'o') { if (o_option) errmsg(ERR_FATAL + ERR_USAGE, "the -o option can only be specified once"); o_option = TRUE; o_option_arg = optarg; } else if (arg == 'Z') { SET_OPTION(Z); } else if (arg == '?') { errmsg(ERR_USAGE, "unknown option: %c", optopt); } } /* * Option sanity checks */ if (g_option && o_option) errmsg(ERR_FATAL, "-o and -g options are incompatible"); if (l_option && o_option) errmsg(ERR_FATAL, "-o and -l options are incompatible"); if (n_option && o_option) errmsg(ERR_FATAL, "-o and -n options are incompatible"); if (use_scaling && o_option) errmsg(ERR_FATAL, "-o and -h options are incompatible"); } /* * Check if the user-specified argument is a resource name. * A resource name is whatever is placed in the mnt_special field of * struct mnttab. In the case of NFS, a resource name has the form * hostname:pathname * We try to find an exact match between the user-specified argument * and the mnt_special field of a mount table entry. * We also use the heuristic of removing the basename from the user-specified * argument and repeating the test until we get a match. This works * fine for NFS but may fail for other remote file system types. However, * it is guaranteed that the function will not fail if the user specifies * the exact resource name. * If successful, this function sets the 'dfr_mte' field of '*dfrp' */ static void resource_mount_entry(struct df_request *dfrp) { char *name; /* * We need our own copy since we will modify the string */ name = new_string(dfrp->dfr_cmd_arg); for (;;) { char *p; int i; /* * Compare against all known mount points. * We start from the most recent mount, which is at the * end of the array. */ for (i = mount_table_entries - 1; i >= 0; i--) { struct mtab_entry *mtep = &mount_table[i]; if (EQ(name, mtep->mte_mount->mnt_special)) { dfrp->dfr_mte = mtep; break; } } /* * Remove the last component of the pathname. * If there is no such component, this is not a resource name. */ p = strrchr(name, '/'); if (p == NULL) break; *p = NUL; } } /* * Try to match the command line argument which is a block special device * with the special device of one of the mounted file systems. * If one is found, set the appropriate field of 'dfrp' to the mount * table entry. */ static void bdev_mount_entry(struct df_request *dfrp) { int i; char *special = dfrp->dfr_cmd_arg; /* * Compare against all known mount points. * We start from the most recent mount, which is at the * end of the array. */ for (i = mount_table_entries - 1; i >= 0; i--) { struct mtab_entry *mtep = &mount_table[i]; if (EQ(special, mtep->mte_mount->mnt_special)) { dfrp->dfr_mte = mtep; break; } } } static struct mtab_entry * devid_matches(int i, dev_t devno) { struct mtab_entry *mtep = &mount_table[i]; struct extmnttab *mtp = mtep->mte_mount; /* int len = strlen(mtp->mnt_mountp); */ if (EQ(mtp->mnt_fstype, MNTTYPE_SWAP)) return (NULL); /* * check if device numbers match. If there is a cached device number * in the mtab_entry, use it, otherwise get the device number * either from the mnttab entry or by stat'ing the mount point. */ if (! mtep->mte_dev_is_valid) { struct stat64 st; dev_t dev = NODEV; dev = makedev(mtp->mnt_major, mtp->mnt_minor); if (dev == 0) dev = NODEV; if (dev == NODEV) { if (stat64(mtp->mnt_mountp, &st) == -1) { return (NULL); } else { dev = st.st_dev; } } mtep->mte_dev = dev; mtep->mte_dev_is_valid = TRUE; } if (mtep->mte_dev == devno) { return (mtep); } return (NULL); } /* * Find the mount point under which the user-specified path resides * and set the 'dfr_mte' field of '*dfrp' to point to the mount table entry. */ static void path_mount_entry(struct df_request *dfrp, dev_t devno) { char dirpath[MAXPATHLEN]; char *dir = dfrp->dfr_cmd_arg; struct mtab_entry *match, *tmatch; int i; /* * Expand the given path to get a canonical version (i.e. an absolute * path without symbolic links). */ if (realpath(dir, dirpath) == NULL) { errmsg(ERR_PERROR, "cannot canonicalize %s:", dir); return; } /* * If the mnt point is lofs, search from the top of entries from * /etc/mnttab and return the first entry that matches the devid * For non-lofs mount points, return the first entry from the bottom * of the entries in /etc/mnttab that matches on the devid field */ match = NULL; if (dfrp->dfr_fstype && EQ(dfrp->dfr_fstype, MNTTYPE_LOFS)) { for (i = 0; i < mount_table_entries; i++) { if (match = devid_matches(i, devno)) break; } } else { for (i = mount_table_entries - 1; i >= 0; i--) { if (tmatch = devid_matches(i, devno)) { /* * If executing in a zone, there might be lofs * mounts for which the real mount point is * invisible; accept the "best fit" for this * devid. */ match = tmatch; if (!EQ(match->mte_mount->mnt_fstype, MNTTYPE_LOFS)) { break; } } } } if (! match) { errmsg(ERR_NOFLAGS, "Could not find mount point for %s", dir); return; } dfrp->dfr_mte = match; } /* * Execute a single FS-specific df command for all given requests * Return 0 if successful, 1 otherwise. */ static int run_fs_specific_df(struct df_request request_list[], int entries) { int i; int argv_index; char **argv; size_t size; pid_t pid; int status; char cmd_path[MAXPATHLEN]; char *fstype; if (entries == 0) return (0); fstype = request_list[0].dfr_fstype; if (F_option && ! EQ(FSType, fstype)) return (0); (void) sprintf(cmd_path, "%s%s/df", FS_LIBPATH, fstype); /* * Argv entries: * 1 for the path * 2 for -o * 1 for the generic options that we propagate * 1 for the terminating NULL pointer * n for the number of user-specified arguments */ size = (5 + entries) * sizeof (char *); argv = xmalloc(size); (void) memset(argv, 0, size); argv[0] = cmd_path; argv_index = 1; if (o_option) { argv[argv_index++] = "-o"; argv[argv_index++] = o_option_arg; } /* * Check if we need to propagate any generic options */ if (df_options_len > 1) argv[argv_index++] = df_options; /* * If there is a user-specified path, we pass that to the * FS-specific df. Otherwise, we are guaranteed to have a mount * point, since a request without a user path implies that * we are reporting only on mounted file systems. */ for (i = 0; i < entries; i++) { struct df_request *dfrp = &request_list[i]; argv[argv_index++] = (dfrp->dfr_cmd_arg == NULL) ? DFR_MOUNT_POINT(dfrp) : dfrp->dfr_cmd_arg; } if (V_option) { for (i = 0; i < argv_index-1; i++) (void) printf("%s ", argv[i]); (void) printf("%s\n", argv[i]); return (0); } pid = fork(); if (pid == -1) { errmsg(ERR_PERROR, "cannot fork process:"); return (1); } else if (pid == 0) { (void) execv(cmd_path, argv); if (errno == ENOENT) errmsg(ERR_NOFLAGS, "operation not applicable for FSType %s", fstype); else errmsg(ERR_PERROR, "cannot execute %s:", cmd_path); exit(2); } /* * Reap the child */ for (;;) { pid_t wpid = waitpid(pid, &status, 0); if (wpid == -1) if (errno == EINTR) continue; else { errmsg(ERR_PERROR, "waitpid error:"); return (1); } else break; } return ((WIFEXITED(status) && WEXITSTATUS(status) == 0) ? 0 : 1); } /* * Remove from the request list all requests that do not apply. * Notice that the subsequent processing of the requests depends on * the sanity checking performed by this function. */ static int prune_list(struct df_request request_list[], size_t n_requests, size_t *valid_requests) { size_t i; size_t n_valid = 0; int errors = 0; for (i = 0; i < n_requests; i++) { struct df_request *dfrp = &request_list[i]; /* * Skip file systems that are not mounted if either the * -l or -n options were specified. If none of these options * are present, the appropriate FS-specific df will be invoked. */ if (! DFR_ISMOUNTEDFS(dfrp)) { if (l_option || n_option) { errmsg(ERR_NOFLAGS, "%s option incompatible with unmounted " "special device (%s)", l_option ? "-l" : "-n", dfrp->dfr_cmd_arg); dfrp->dfr_valid = FALSE; errors++; } else n_valid++; continue; } /* * Check for inconsistency between the argument of -F and * the actual file system type. * If there is an inconsistency and the user specified a * path, this is an error since we are asked to interpret * the path using the wrong file system type. If there is * no path associated with this request, we quietly ignore it. */ if (F_option && ! EQ(dfrp->dfr_fstype, FSType)) { dfrp->dfr_valid = FALSE; if (dfrp->dfr_cmd_arg != NULL) { errmsg(ERR_NOFLAGS, "Warning: %s mounted as a %s file system", dfrp->dfr_cmd_arg, dfrp->dfr_fstype); errors++; } continue; } /* * Skip remote file systems if the -l option is present */ if (l_option && is_remote_fs(dfrp->dfr_fstype)) { if (dfrp->dfr_cmd_arg != NULL) { errmsg(ERR_NOFLAGS, "Warning: %s is not a local file system", dfrp->dfr_cmd_arg); errors++; } dfrp->dfr_valid = FALSE; continue; } /* * Skip file systems mounted as "ignore" unless the -a option * is present, or the user explicitly specified them on * the command line. */ if (dfrp->dfr_mte->mte_ignore && ! (a_option || dfrp->dfr_cmd_arg)) { dfrp->dfr_valid = FALSE; continue; } n_valid++; } *valid_requests = n_valid; return (errors); } /* * Print the appropriate header for the requested output format. * Options are checked in order of their precedence. */ static void print_header(void) { if (use_scaling) { /* this comes from the -h option */ int arg = 'h'; (void) printf("%-*s %*s %*s %*s %-*s %s\n", FILESYSTEM_WIDTH, TRANSLATE("Filesystem"), #ifdef XPG4 SCALED_WIDTH, TRANSLATE("Size"), SCALED_WIDTH, TRANSLATE("Used"), AVAILABLE_WIDTH, TRANSLATE("Available"), CAPACITY_WIDTH, TRANSLATE("Capacity"), #else SCALED_WIDTH, TRANSLATE("size"), SCALED_WIDTH, TRANSLATE("used"), AVAILABLE_WIDTH, TRANSLATE("avail"), CAPACITY_WIDTH, TRANSLATE("capacity"), #endif TRANSLATE("Mounted on")); SET_OPTION(h); return; } if (k_option) { int arg = 'h'; (void) printf(gettext("%-*s %*s %*s %*s %-*s %s\n"), FILESYSTEM_WIDTH, TRANSLATE("Filesystem"), #ifdef XPG4 KBYTE_WIDTH, TRANSLATE("1024-blocks"), KBYTE_WIDTH, TRANSLATE("Used"), KBYTE_WIDTH, TRANSLATE("Available"), CAPACITY_WIDTH, TRANSLATE("Capacity"), #else KBYTE_WIDTH, TRANSLATE("kbytes"), KBYTE_WIDTH, TRANSLATE("used"), KBYTE_WIDTH, TRANSLATE("avail"), CAPACITY_WIDTH, TRANSLATE("capacity"), #endif TRANSLATE("Mounted on")); SET_OPTION(h); return; } /* Added for XCU4 compliance */ if (P_option) { int arg = 'h'; (void) printf(gettext("%-*s %*s %*s %*s %-*s %s\n"), FILESYSTEM_WIDTH, TRANSLATE("Filesystem"), KBYTE_WIDTH, TRANSLATE("512-blocks"), KBYTE_WIDTH, TRANSLATE("Used"), KBYTE_WIDTH, TRANSLATE("Available"), CAPACITY_WIDTH, TRANSLATE("Capacity"), TRANSLATE("Mounted on")); SET_OPTION(h); return; } /* End XCU4 */ if (v_option) { (void) printf("%-*s %-*s %*s %*s %*s %-*s\n", IBCS2_MOUNT_POINT_WIDTH, TRANSLATE("Mount Dir"), IBCS2_FILESYSTEM_WIDTH, TRANSLATE("Filesystem"), BLOCK_WIDTH, TRANSLATE("blocks"), BLOCK_WIDTH, TRANSLATE("used"), BLOCK_WIDTH, TRANSLATE("free"), CAPACITY_WIDTH, TRANSLATE(" %used")); return; } if (e_option) { (void) printf(gettext("%-*s %*s\n"), FILESYSTEM_WIDTH, TRANSLATE("Filesystem"), BLOCK_WIDTH, TRANSLATE("ifree")); return; } if (b_option) { (void) printf(gettext("%-*s %*s\n"), FILESYSTEM_WIDTH, TRANSLATE("Filesystem"), BLOCK_WIDTH, TRANSLATE("avail")); return; } } /* * Convert an unsigned long long to a string representation and place the * result in the caller-supplied buffer. * The given number is in units of "unit_from" size, but the * converted number will be in units of "unit_to" size. The unit sizes * must be powers of 2. * The value "(unsigned long long)-1" is a special case and is always * converted to "-1". * Returns a pointer to the caller-supplied buffer. */ static char * number_to_string( char *buf, /* put the result here */ unsigned long long number, /* convert this number */ int unit_from, /* from units of this size */ int unit_to) /* to units of this size */ { if ((long long)number == (long long)-1) (void) strcpy(buf, "-1"); else { if (unit_from == unit_to) (void) sprintf(buf, "%llu", number); else if (unit_from < unit_to) (void) sprintf(buf, "%llu", number / (unsigned long long)(unit_to / unit_from)); else (void) sprintf(buf, "%llu", number * (unsigned long long)(unit_from / unit_to)); } return (buf); } /* * Convert an unsigned long long to a string representation and place the * result in the caller-supplied buffer. * The given number is in units of "unit_from" size, * this will first be converted to a number in 1024 or 1000 byte size, * depending on the scaling factor. * Then the number is scaled down until it is small enough to be in a good * human readable format i.e. in the range 0 thru scale-1. * If it's smaller than 10 there's room enough to provide one decimal place. * The value "(unsigned long long)-1" is a special case and is always * converted to "-1". * Returns a pointer to the caller-supplied buffer. */ static char * number_to_scaled_string( numbuf_t buf, /* put the result here */ unsigned long long number, /* convert this number */ int unit_from, int scale) { unsigned long long save = 0; char *M = "KMGTPE"; /* Measurement: kilo, mega, giga, tera, peta, exa */ char *uom = M; /* unit of measurement, initially 'K' (=M[0]) */ if ((long long)number == (long long)-1) { (void) strcpy(buf, "-1"); return (buf); } /* * Convert number from unit_from to given scale (1024 or 1000). * This means multiply number by unit_from and divide by scale. * * Would like to multiply by unit_from and then divide by scale, * but if the first multiplication would overflow, then need to * divide by scale and then multiply by unit_from. */ if (number > (UINT64_MAX / (unsigned long long)unit_from)) { number = (number / (unsigned long long)scale) * (unsigned long long)unit_from; } else { number = (number * (unsigned long long)unit_from) / (unsigned long long)scale; } /* * Now we have number as a count of scale units. * Stop scaling when we reached exa bytes, then something is * probably wrong with our number. */ while ((number >= scale) && (*uom != 'E')) { uom++; /* next unit of measurement */ save = number; number = (number + (scale / 2)) / scale; } /* check if we should output a decimal place after the point */ if (save && ((save / scale) < 10)) { /* sprintf() will round for us */ float fnum = (float)save / scale; (void) sprintf(buf, "%2.1f%c", fnum, *uom); } else { (void) sprintf(buf, "%4llu%c", number, *uom); } return (buf); } /* * The statvfs() implementation allows us to return only two values, the total * number of blocks and the number of blocks free. The equation 'used = total - * free' will not work for ZFS filesystems, due to the nature of pooled storage. * We choose to return values in the statvfs structure that will produce correct * results for 'used' and 'available', but not 'total'. This function will open * the underlying ZFS dataset if necessary and get the real value. */ static void adjust_total_blocks(struct df_request *dfrp, fsblkcnt64_t *total, uint64_t blocksize) { char *dataset, *slash; boolean_t first = TRUE; uint64_t quota = 0; if (strcmp(DFR_FSTYPE(dfrp), MNTTYPE_ZFS) != 0 || !load_libzfs()) return; /* * We want to get the total size for this filesystem as bounded by any * quotas. In order to do this, we start at the current filesystem and * work upwards looking for the smallest quota. When we reach the * pool itself, the quota is the amount used plus the amount * available. */ if ((dataset = strdup(DFR_SPECIAL(dfrp))) == NULL) return; slash = dataset + strlen(dataset); while (slash != NULL) { zfs_handle_t *zhp; uint64_t this_quota; *slash = '\0'; zhp = _zfs_open(g_zfs, dataset, ZFS_TYPE_DATASET); if (zhp == NULL) break; /* true at first iteration of loop */ if (first) { quota = _zfs_prop_get_int(zhp, ZFS_PROP_REFQUOTA); if (quota == 0) quota = UINT64_MAX; first = FALSE; } this_quota = _zfs_prop_get_int(zhp, ZFS_PROP_QUOTA); if (this_quota && this_quota < quota) quota = this_quota; /* true at last iteration of loop */ if ((slash = strrchr(dataset, '/')) == NULL) { uint64_t size; size = _zfs_prop_get_int(zhp, ZFS_PROP_USED) + _zfs_prop_get_int(zhp, ZFS_PROP_AVAILABLE); if (size < quota) quota = size; } _zfs_close(zhp); } /* * Modify total only if we managed to get some stats from libzfs. */ if (quota != 0) *total = quota / blocksize; free(dataset); } /* * The output will appear properly columnized regardless of the names of * the various fields */ static void g_output(struct df_request *dfrp, struct statvfs64 *fsp) { fsblkcnt64_t available_blocks = fsp->f_bavail; fsblkcnt64_t total_blocks = fsp->f_blocks; numbuf_t total_blocks_buf; numbuf_t total_files_buf; numbuf_t free_blocks_buf; numbuf_t available_blocks_buf; numbuf_t free_files_buf; numbuf_t fname_buf; char *temp_buf; #define DEFINE_STR_LEN(var) \ static char *var##_str; \ static size_t var##_len #define SET_STR_LEN(name, var)\ if (! var##_str) {\ var##_str = TRANSLATE(name); \ var##_len = strlen(var##_str); \ } DEFINE_STR_LEN(block_size); DEFINE_STR_LEN(frag_size); DEFINE_STR_LEN(total_blocks); DEFINE_STR_LEN(free_blocks); DEFINE_STR_LEN(available); DEFINE_STR_LEN(total_files); DEFINE_STR_LEN(free_files); DEFINE_STR_LEN(fstype); DEFINE_STR_LEN(fsys_id); DEFINE_STR_LEN(fname); DEFINE_STR_LEN(flag); /* * TRANSLATION_NOTE * The first argument of each of the following macro invocations is a * string that needs to be translated. */ SET_STR_LEN("block size", block_size); SET_STR_LEN("frag size", frag_size); SET_STR_LEN("total blocks", total_blocks); SET_STR_LEN("free blocks", free_blocks); SET_STR_LEN("available", available); SET_STR_LEN("total files", total_files); SET_STR_LEN("free files", free_files); SET_STR_LEN("fstype", fstype); SET_STR_LEN("filesys id", fsys_id); SET_STR_LEN("filename length", fname); SET_STR_LEN("flag", flag); #define NCOL1_WIDTH (int)MAX3(BLOCK_WIDTH, NFILES_WIDTH, FSTYPE_WIDTH) #define NCOL2_WIDTH (int)MAX3(BLOCK_WIDTH, FSID_WIDTH, FLAG_WIDTH) + 2 #define NCOL3_WIDTH (int)MAX3(BSIZE_WIDTH, BLOCK_WIDTH, NAMELEN_WIDTH) #define NCOL4_WIDTH (int)MAX(FRAGSIZE_WIDTH, NFILES_WIDTH) #define SCOL1_WIDTH (int)MAX3(total_blocks_len, free_files_len, fstype_len) #define SCOL2_WIDTH (int)MAX3(free_blocks_len, fsys_id_len, flag_len) #define SCOL3_WIDTH (int)MAX3(block_size_len, available_len, fname_len) #define SCOL4_WIDTH (int)MAX(frag_size_len, total_files_len) temp_buf = xmalloc( MAX(MOUNT_POINT_WIDTH, strlen(DFR_MOUNT_POINT(dfrp))) + MAX(SPECIAL_DEVICE_WIDTH, strlen(DFR_SPECIAL(dfrp))) + 20); /* plus slop - nulls & formatting */ (void) sprintf(temp_buf, "%-*s(%-*s):", MOUNT_POINT_WIDTH, DFR_MOUNT_POINT(dfrp), SPECIAL_DEVICE_WIDTH, DFR_SPECIAL(dfrp)); (void) printf("%-*s %*lu %-*s %*lu %-*s\n", NCOL1_WIDTH + 1 + SCOL1_WIDTH + 1 + NCOL2_WIDTH + 1 + SCOL2_WIDTH, temp_buf, NCOL3_WIDTH, fsp->f_bsize, SCOL3_WIDTH, block_size_str, NCOL4_WIDTH, fsp->f_frsize, SCOL4_WIDTH, frag_size_str); free(temp_buf); /* * Adjust available_blocks value - it can be less than 0 on * a 4.x file system. Reset it to 0 in order to avoid printing * negative numbers. */ if ((long long)available_blocks < (long long)0) available_blocks = (fsblkcnt64_t)0; adjust_total_blocks(dfrp, &total_blocks, fsp->f_frsize); (void) printf("%*s %-*s %*s %-*s %*s %-*s %*s %-*s\n", NCOL1_WIDTH, number_to_string(total_blocks_buf, total_blocks, fsp->f_frsize, 512), SCOL1_WIDTH, total_blocks_str, NCOL2_WIDTH, number_to_string(free_blocks_buf, fsp->f_bfree, fsp->f_frsize, 512), SCOL2_WIDTH, free_blocks_str, NCOL3_WIDTH, number_to_string(available_blocks_buf, available_blocks, fsp->f_frsize, 512), SCOL3_WIDTH, available_str, NCOL4_WIDTH, number_to_string(total_files_buf, fsp->f_files, 1, 1), SCOL4_WIDTH, total_files_str); (void) printf("%*s %-*s %*lu %-*s %s\n", NCOL1_WIDTH, number_to_string(free_files_buf, fsp->f_ffree, 1, 1), SCOL1_WIDTH, free_files_str, NCOL2_WIDTH, fsp->f_fsid, SCOL2_WIDTH, fsys_id_str, fsp->f_fstr); (void) printf("%*s %-*s %#*.*lx %-*s %*s %-*s\n\n", NCOL1_WIDTH, fsp->f_basetype, SCOL1_WIDTH, fstype_str, NCOL2_WIDTH, NCOL2_WIDTH-2, fsp->f_flag, SCOL2_WIDTH, flag_str, NCOL3_WIDTH, number_to_string(fname_buf, (unsigned long long)fsp->f_namemax, 1, 1), SCOL3_WIDTH, fname_str); } static void k_output(struct df_request *dfrp, struct statvfs64 *fsp) { fsblkcnt64_t total_blocks = fsp->f_blocks; fsblkcnt64_t free_blocks = fsp->f_bfree; fsblkcnt64_t available_blocks = fsp->f_bavail; fsblkcnt64_t used_blocks; char *file_system = DFR_SPECIAL(dfrp); numbuf_t total_blocks_buf; numbuf_t used_blocks_buf; numbuf_t available_blocks_buf; char capacity_buf[LINEBUF_SIZE]; /* * If the free block count is -1, don't trust anything but the total * number of blocks. */ if (free_blocks == (fsblkcnt64_t)-1) { used_blocks = (fsblkcnt64_t)-1; (void) strcpy(capacity_buf, " 100%"); } else { fsblkcnt64_t reserved_blocks = free_blocks - available_blocks; used_blocks = total_blocks - free_blocks; /* * The capacity estimation is bogus when available_blocks is 0 * and the super-user has allocated more space. The reason * is that reserved_blocks is inaccurate in that case, because * when the super-user allocates space, free_blocks is updated * but available_blocks is not (since it can't drop below 0). * * XCU4 and POSIX.2 require that any fractional result of the * capacity estimation be rounded to the next highest integer, * hence the addition of 0.5. */ (void) sprintf(capacity_buf, "%5.0f%%", (total_blocks == 0) ? 0.0 : ((double)used_blocks / (double)(total_blocks - reserved_blocks)) * 100.0 + 0.5); } /* * The available_blocks can be less than 0 on a 4.x file system. * Reset it to 0 in order to avoid printing negative numbers. */ if ((long long)available_blocks < (long long)0) available_blocks = (fsblkcnt64_t)0; /* * Print long special device names (usually NFS mounts) in a line * by themselves when the output is directed to a terminal. */ if (tty_output && strlen(file_system) > (size_t)FILESYSTEM_WIDTH) { (void) printf("%s\n", file_system); file_system = ""; } adjust_total_blocks(dfrp, &total_blocks, fsp->f_frsize); if (use_scaling) { /* comes from the -h option */ (void) printf("%-*s %*s %*s %*s %-*s %-s\n", FILESYSTEM_WIDTH, file_system, SCALED_WIDTH, number_to_scaled_string(total_blocks_buf, total_blocks, fsp->f_frsize, scale), SCALED_WIDTH, number_to_scaled_string(used_blocks_buf, used_blocks, fsp->f_frsize, scale), AVAILABLE_WIDTH, number_to_scaled_string(available_blocks_buf, available_blocks, fsp->f_frsize, scale), CAPACITY_WIDTH, capacity_buf, DFR_MOUNT_POINT(dfrp)); return; } if (v_option) { (void) printf("%-*.*s %-*.*s %*lld %*lld %*lld %-.*s\n", IBCS2_MOUNT_POINT_WIDTH, IBCS2_MOUNT_POINT_WIDTH, DFR_MOUNT_POINT(dfrp), IBCS2_FILESYSTEM_WIDTH, IBCS2_FILESYSTEM_WIDTH, file_system, BLOCK_WIDTH, total_blocks, BLOCK_WIDTH, used_blocks, BLOCK_WIDTH, available_blocks, CAPACITY_WIDTH, capacity_buf); return; } if (P_option && !k_option) { (void) printf("%-*s %*s %*s %*s %-*s %-s\n", FILESYSTEM_WIDTH, file_system, KBYTE_WIDTH, number_to_string(total_blocks_buf, total_blocks, fsp->f_frsize, 512), KBYTE_WIDTH, number_to_string(used_blocks_buf, used_blocks, fsp->f_frsize, 512), KBYTE_WIDTH, number_to_string(available_blocks_buf, available_blocks, fsp->f_frsize, 512), CAPACITY_WIDTH, capacity_buf, DFR_MOUNT_POINT(dfrp)); } else { (void) printf("%-*s %*s %*s %*s %-*s %-s\n", FILESYSTEM_WIDTH, file_system, KBYTE_WIDTH, number_to_string(total_blocks_buf, total_blocks, fsp->f_frsize, 1024), KBYTE_WIDTH, number_to_string(used_blocks_buf, used_blocks, fsp->f_frsize, 1024), KBYTE_WIDTH, number_to_string(available_blocks_buf, available_blocks, fsp->f_frsize, 1024), CAPACITY_WIDTH, capacity_buf, DFR_MOUNT_POINT(dfrp)); } } /* * The following is for internationalization support. */ static bool_int strings_initialized; static char *files_str; static char *blocks_str; static char *total_str; static char *kilobytes_str; static void strings_init(void) { total_str = TRANSLATE("total"); #ifdef _iBCS2 /* ISC/SCO print i-nodes instead of files */ if (sysv3_set) files_str = TRANSLATE("i-nodes"); else #endif /* _iBCS2 */ files_str = TRANSLATE("files"); blocks_str = TRANSLATE("blocks"); kilobytes_str = TRANSLATE("kilobytes"); strings_initialized = TRUE; } #define STRINGS_INIT() if (!strings_initialized) strings_init() static void t_output(struct df_request *dfrp, struct statvfs64 *fsp) { fsblkcnt64_t total_blocks = fsp->f_blocks; numbuf_t total_blocks_buf; numbuf_t total_files_buf; numbuf_t free_blocks_buf; numbuf_t free_files_buf; STRINGS_INIT(); adjust_total_blocks(dfrp, &total_blocks, fsp->f_frsize); (void) printf("%-*s(%-*s): %*s %s %*s %s\n", MOUNT_POINT_WIDTH, DFR_MOUNT_POINT(dfrp), SPECIAL_DEVICE_WIDTH, DFR_SPECIAL(dfrp), BLOCK_WIDTH, number_to_string(free_blocks_buf, fsp->f_bfree, fsp->f_frsize, 512), blocks_str, NFILES_WIDTH, number_to_string(free_files_buf, fsp->f_ffree, 1, 1), files_str); /* * The total column used to use the same space as the mnt pt & special * dev fields. However, this doesn't work with massive special dev * fields * (eg > 500 chars) causing an enormous amount of white space * before the total column (see bug 4100411). So the code was * simplified to set the total column at the usual gap. * This had the side effect of fixing a bug where the previously * used static buffer was overflowed by the same massive special dev. */ (void) printf("%*s: %*s %s %*s %s\n", MNT_SPEC_WIDTH, total_str, BLOCK_WIDTH, number_to_string(total_blocks_buf, total_blocks, fsp->f_frsize, 512), blocks_str, NFILES_WIDTH, number_to_string(total_files_buf, fsp->f_files, 1, 1), files_str); } static void eb_output(struct df_request *dfrp, struct statvfs64 *fsp) { numbuf_t free_files_buf; numbuf_t free_kbytes_buf; STRINGS_INIT(); (void) printf("%-*s(%-*s): %*s %s\n", MOUNT_POINT_WIDTH, DFR_MOUNT_POINT(dfrp), SPECIAL_DEVICE_WIDTH, DFR_SPECIAL(dfrp), MAX(KBYTE_WIDTH, NFILES_WIDTH), number_to_string(free_kbytes_buf, fsp->f_bfree, fsp->f_frsize, 1024), kilobytes_str); (void) printf("%-*s(%-*s): %*s %s\n", MOUNT_POINT_WIDTH, DFR_MOUNT_POINT(dfrp), SPECIAL_DEVICE_WIDTH, DFR_SPECIAL(dfrp), MAX(NFILES_WIDTH, NFILES_WIDTH), number_to_string(free_files_buf, fsp->f_ffree, 1, 1), files_str); } static void e_output(struct df_request *dfrp, struct statvfs64 *fsp) { numbuf_t free_files_buf; (void) printf("%-*s %*s\n", FILESYSTEM_WIDTH, DFR_SPECIAL(dfrp), NFILES_WIDTH, number_to_string(free_files_buf, fsp->f_ffree, 1, 1)); } static void b_output(struct df_request *dfrp, struct statvfs64 *fsp) { numbuf_t free_blocks_buf; (void) printf("%-*s %*s\n", FILESYSTEM_WIDTH, DFR_SPECIAL(dfrp), BLOCK_WIDTH, number_to_string(free_blocks_buf, fsp->f_bfree, fsp->f_frsize, 1024)); } /* ARGSUSED */ static void n_output(struct df_request *dfrp, struct statvfs64 *fsp) { (void) printf("%-*s: %-*s\n", MOUNT_POINT_WIDTH, DFR_MOUNT_POINT(dfrp), FSTYPE_WIDTH, dfrp->dfr_fstype); } static void default_output(struct df_request *dfrp, struct statvfs64 *fsp) { numbuf_t free_blocks_buf; numbuf_t free_files_buf; STRINGS_INIT(); (void) printf("%-*s(%-*s):%*s %s %*s %s\n", MOUNT_POINT_WIDTH, DFR_MOUNT_POINT(dfrp), SPECIAL_DEVICE_WIDTH, DFR_SPECIAL(dfrp), BLOCK_WIDTH, number_to_string(free_blocks_buf, fsp->f_bfree, fsp->f_frsize, 512), blocks_str, NFILES_WIDTH, number_to_string(free_files_buf, fsp->f_ffree, 1, 1), files_str); } /* ARGSUSED */ static void V_output(struct df_request *dfrp, struct statvfs64 *fsp) { char temp_buf[LINEBUF_SIZE]; if (df_options_len > 1) (void) strcat(strcpy(temp_buf, df_options), " "); else temp_buf[0] = NUL; (void) printf("%s -F %s %s%s\n", program_name, dfrp->dfr_fstype, temp_buf, dfrp->dfr_cmd_arg ? dfrp->dfr_cmd_arg: DFR_SPECIAL(dfrp)); } /* * This function is used to sort the array of df_requests according to fstype */ static int df_reqcomp(const void *p1, const void *p2) { int v = strcmp(DFRP(p1)->dfr_fstype, DFRP(p2)->dfr_fstype); if (v != 0) return (v); else return (DFRP(p1)->dfr_index - DFRP(p2)->dfr_index); } static void vfs_error(char *file, int status) { if (status == VFS_TOOLONG) errmsg(ERR_NOFLAGS, "a line in %s exceeds %d characters", file, MNT_LINE_MAX); else if (status == VFS_TOOMANY) errmsg(ERR_NOFLAGS, "a line in %s has too many fields", file); else if (status == VFS_TOOFEW) errmsg(ERR_NOFLAGS, "a line in %s has too few fields", file); else errmsg(ERR_NOFLAGS, "error while reading %s: %d", file, status); } /* * Try to determine the fstype for the specified block device. * Return in order of decreasing preference: * file system type from vfstab * file system type as specified by -F option * default file system type */ static char * find_fstype(char *special) { struct vfstab vtab; FILE *fp; int status; char *vfstab_file = VFS_TAB; fp = xfopen(vfstab_file); status = getvfsspec(fp, &vtab, special); (void) fclose(fp); if (status > 0) vfs_error(vfstab_file, status); if (status == 0) { if (F_option && ! EQ(FSType, vtab.vfs_fstype)) errmsg(ERR_NOFLAGS, "warning: %s is of type %s", special, vtab.vfs_fstype); return (new_string(vtab.vfs_fstype)); } else return (F_option ? FSType : default_fstype(special)); } /* * When this function returns, the following fields are filled for all * valid entries in the requests[] array: * dfr_mte (if the file system is mounted) * dfr_fstype * dfr_index * * The function returns the number of errors that occurred while building * the request list. */ static int create_request_list( int argc, char *argv[], struct df_request *requests_p[], size_t *request_count) { struct df_request *requests; struct df_request *dfrp; size_t size; size_t i; size_t request_index = 0; size_t max_requests; int errors = 0; /* * If no args, use the mounted file systems, otherwise use the * user-specified arguments. */ if (argc == 0) { mtab_read_file(); max_requests = mount_table_entries; } else max_requests = argc; size = max_requests * sizeof (struct df_request); requests = xmalloc(size); (void) memset(requests, 0, size); if (argc == 0) { /* * If -Z wasn't specified, we skip mounts in other * zones. This obviously is a noop in a non-global * zone. */ boolean_t showall = (getzoneid() != GLOBAL_ZONEID) || Z_option; struct zone_summary *zsp; if (!showall) { zsp = fs_get_zone_summaries(); if (zsp == NULL) errmsg(ERR_FATAL, "unable to retrieve list of zones"); } for (i = 0; i < mount_table_entries; i++) { struct extmnttab *mtp = mount_table[i].mte_mount; if (EQ(mtp->mnt_fstype, MNTTYPE_SWAP)) continue; if (!showall) { if (fs_mount_in_other_zone(zsp, mtp->mnt_mountp)) continue; } dfrp = &requests[request_index++]; dfrp->dfr_mte = &mount_table[i]; dfrp->dfr_fstype = mtp->mnt_fstype; dfrp->dfr_index = i; dfrp->dfr_valid = TRUE; } } else { struct stat64 *arg_stat; /* array of stat structures */ bool_int *valid_stat; /* which structures are valid */ arg_stat = xmalloc(argc * sizeof (struct stat64)); valid_stat = xmalloc(argc * sizeof (bool_int)); /* * Obtain stat64 information for each argument before * constructing the list of mounted file systems. By * touching all these places we force 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. * It is still possible that the automounter may timeout * mounts between the time we read the mount table and the * time we process the request. Even in that case, when * we issue the statvfs64(2) for the mount point, the file * system will be mounted again. The only problem will * occur if the automounter maps change in the meantime * and the mount point is eliminated. */ for (i = 0; i < argc; i++) valid_stat[i] = (stat64(argv[i], &arg_stat[i]) == 0); mtab_read_file(); for (i = 0; i < argc; i++) { char *arg = argv[i]; dfrp = &requests[request_index]; dfrp->dfr_index = request_index; dfrp->dfr_cmd_arg = arg; if (valid_stat[i]) { if (S_ISBLK(arg_stat[i].st_mode)) { bdev_mount_entry(dfrp); dfrp->dfr_valid = TRUE; } else if (S_ISDIR(arg_stat[i].st_mode) || S_ISREG(arg_stat[i].st_mode) || S_ISFIFO(arg_stat[i].st_mode)) { path_mount_entry(dfrp, arg_stat[i].st_dev); if (! DFR_ISMOUNTEDFS(dfrp)) { errors++; continue; } dfrp->dfr_valid = TRUE; } } else { resource_mount_entry(dfrp); dfrp->dfr_valid = DFR_ISMOUNTEDFS(dfrp); } /* * If we haven't managed to verify that the request * is valid, we must have gotten a bad argument. */ if (!dfrp->dfr_valid) { errmsg(ERR_NOFLAGS, "(%-10s) not a block device, directory or " "mounted resource", arg); errors++; continue; } /* * Determine the file system type. */ if (DFR_ISMOUNTEDFS(dfrp)) dfrp->dfr_fstype = dfrp->dfr_mte->mte_mount->mnt_fstype; else dfrp->dfr_fstype = find_fstype(dfrp->dfr_cmd_arg); request_index++; } } *requests_p = requests; *request_count = request_index; return (errors); } /* * Select the appropriate function and flags to use for output. * Notice that using both -e and -b options produces a different form of * output than either of those two options alone; this is the behavior of * the SVR4 df. */ static struct df_output * select_output(void) { static struct df_output dfo; /* * The order of checking options follows the option precedence * rules as they are listed in the man page. */ if (use_scaling) { /* comes from the -h option */ dfo.dfo_func = k_output; dfo.dfo_flags = DFO_HEADER + DFO_STATVFS; } else if (V_option) { dfo.dfo_func = V_output; dfo.dfo_flags = DFO_NOFLAGS; } else if (g_option) { dfo.dfo_func = g_output; dfo.dfo_flags = DFO_STATVFS; } else if (k_option || P_option || v_option) { dfo.dfo_func = k_output; dfo.dfo_flags = DFO_HEADER + DFO_STATVFS; } else if (t_option) { dfo.dfo_func = t_output; dfo.dfo_flags = DFO_STATVFS; } else if (b_option && e_option) { dfo.dfo_func = eb_output; dfo.dfo_flags = DFO_STATVFS; } else if (b_option) { dfo.dfo_func = b_output; dfo.dfo_flags = DFO_HEADER + DFO_STATVFS; } else if (e_option) { dfo.dfo_func = e_output; dfo.dfo_flags = DFO_HEADER + DFO_STATVFS; } else if (n_option) { dfo.dfo_func = n_output; dfo.dfo_flags = DFO_NOFLAGS; } else { dfo.dfo_func = default_output; dfo.dfo_flags = DFO_STATVFS; } return (&dfo); } /* * The (argc,argv) pair contains all the non-option arguments */ static void do_df(int argc, char *argv[]) { size_t i; struct df_request *requests; /* array of requests */ size_t n_requests; struct df_request *dfrp; int errors; errors = create_request_list(argc, argv, &requests, &n_requests); if (n_requests == 0) exit(errors); /* * If we are going to run the FSType-specific df command, * rearrange the requests so that we can issue a single command * per file system type. */ if (o_option) { size_t j; /* * qsort is not a stable sorting method (i.e. requests of * the same file system type may be swapped, and hence appear * in the output in a different order from the one in which * they were listed in the command line). In order to force * stability, we use the dfr_index field which is unique * for each request. */ qsort(requests, n_requests, sizeof (struct df_request), df_reqcomp); for (i = 0; i < n_requests; i = j) { char *fstype = requests[i].dfr_fstype; for (j = i+1; j < n_requests; j++) if (! EQ(fstype, requests[j].dfr_fstype)) break; /* * At this point, requests in the range [i,j) are * of the same type. * * If the -F option was used, and the user specified * arguments, the filesystem types must match * * XXX: the alternative of doing this check here is to * invoke prune_list, but then we have to * modify this code to ignore invalid requests. */ if (F_option && ! EQ(fstype, FSType)) { size_t k; for (k = i; k < j; k++) { dfrp = &requests[k]; if (dfrp->dfr_cmd_arg != NULL) { errmsg(ERR_NOFLAGS, "Warning: %s mounted as a " "%s file system", dfrp->dfr_cmd_arg, dfrp->dfr_fstype); errors++; } } } else errors += run_fs_specific_df(&requests[i], j-i); } } else { size_t valid_requests; /* * We have to prune the request list to avoid printing a header * if there are no valid requests */ errors += prune_list(requests, n_requests, &valid_requests); if (valid_requests) { struct df_output *dfop = select_output(); /* indicates if we already printed out a header line */ int printed_header = 0; for (i = 0; i < n_requests; i++) { dfrp = &requests[i]; if (! dfrp->dfr_valid) continue; /* * If we don't have a mount point, * this must be a block device. */ if (DFR_ISMOUNTEDFS(dfrp)) { struct statvfs64 stvfs; if ((dfop->dfo_flags & DFO_STATVFS) && statvfs64(DFR_MOUNT_POINT(dfrp), &stvfs) == -1) { errmsg(ERR_PERROR, "cannot statvfs %s:", DFR_MOUNT_POINT(dfrp)); errors++; continue; } if ((!printed_header) && (dfop->dfo_flags & DFO_HEADER)) { print_header(); printed_header = 1; } (*dfop->dfo_func)(dfrp, &stvfs); } else { /* * -h option only works for * mounted filesystems */ if (use_scaling) { errmsg(ERR_NOFLAGS, "-h option incompatible with unmounted special device (%s)", dfrp->dfr_cmd_arg); errors++; continue; } errors += run_fs_specific_df(dfrp, 1); } } } } exit(errors); } /* * The rest of this file implements the devnm command */ static char * find_dev_name(char *file, dev_t dev) { struct df_request dfreq; dfreq.dfr_cmd_arg = file; dfreq.dfr_fstype = 0; dfreq.dfr_mte = NULL; path_mount_entry(&dfreq, dev); return (DFR_ISMOUNTEDFS(&dfreq) ? DFR_SPECIAL(&dfreq) : NULL); } static void do_devnm(int argc, char *argv[]) { int arg; int errors = 0; char *dev_name; if (argc == 1) errmsg(ERR_NONAME, "Usage: %s name ...", DEVNM_CMD); mtab_read_file(); for (arg = 1; arg < argc; arg++) { char *file = argv[arg]; struct stat64 st; if (stat64(file, &st) == -1) { errmsg(ERR_PERROR, "%s: ", file); errors++; continue; } if (! is_remote_fs(st.st_fstype) && ! EQ(st.st_fstype, MNTTYPE_TMPFS) && (dev_name = find_dev_name(file, st.st_dev))) (void) printf("%s %s\n", dev_name, file); else errmsg(ERR_NOFLAGS, "%s not found", file); } exit(errors); /* NOTREACHED */ }