/* $NetBSD: dmsetup.c,v 1.1.1.2 2009/12/02 00:25:49 haad Exp $ */ /* * Copyright (C) 2001-2004 Sistina Software, Inc. All rights reserved. * Copyright (C) 2004-2008 Red Hat, Inc. All rights reserved. * Copyright (C) 2005-2007 NEC Corporation * * This file is part of the device-mapper userspace tools. * * It includes tree drawing code based on pstree: http://psmisc.sourceforge.net/ * * This copyrighted material is made available to anyone wishing to use, * modify, copy, or redistribute it subject to the terms and conditions * of the GNU General Public License v.2. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software Foundation, * Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #define _GNU_SOURCE #define _FILE_OFFSET_BITS 64 #include "configure.h" #include "dm-logging.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef UDEV_SYNC_SUPPORT # include # include # include #endif /* FIXME Unused so far */ #undef HAVE_SYS_STATVFS_H #ifdef HAVE_SYS_STATVFS_H # include #endif #ifdef HAVE_SYS_IOCTL_H # include #endif #if HAVE_TERMIOS_H # include #endif #ifdef HAVE_GETOPTLONG # include # define GETOPTLONG_FN(a, b, c, d, e) getopt_long((a), (b), (c), (d), (e)) # define OPTIND_INIT 0 #else struct option { }; extern int optind; extern char *optarg; # define GETOPTLONG_FN(a, b, c, d, e) getopt((a), (b), (c)) # define OPTIND_INIT 1 #endif #ifndef TEMP_FAILURE_RETRY # define TEMP_FAILURE_RETRY(expression) \ (__extension__ \ ({ long int __result; \ do __result = (long int) (expression); \ while (__result == -1L && errno == EINTR); \ __result; })) #endif #ifdef linux # include "kdev_t.h" #else # define MAJOR(x) major((x)) # define MINOR(x) minor((x)) # define MKDEV(x,y) makedev((x),(y)) #endif #define LINE_SIZE 4096 #define ARGS_MAX 256 #define LOOP_TABLE_SIZE (PATH_MAX + 255) #define DEFAULT_DM_DEV_DIR "/dev" /* FIXME Should be imported */ #ifndef DM_MAX_TYPE_NAME # define DM_MAX_TYPE_NAME 16 #endif /* FIXME Should be elsewhere */ #define SECTOR_SHIFT 9L #define err(msg, x...) fprintf(stderr, msg "\n", ##x) /* * We have only very simple switches ATM. */ enum { READ_ONLY = 0, COLS_ARG, EXEC_ARG, FORCE_ARG, GID_ARG, INACTIVE_ARG, MAJOR_ARG, MINOR_ARG, MODE_ARG, NAMEPREFIXES_ARG, NOFLUSH_ARG, NOHEADINGS_ARG, NOLOCKFS_ARG, NOOPENCOUNT_ARG, NOTABLE_ARG, NOUDEVSYNC_ARG, OPTIONS_ARG, READAHEAD_ARG, ROWS_ARG, SEPARATOR_ARG, SHOWKEYS_ARG, SORT_ARG, TABLE_ARG, TARGET_ARG, TREE_ARG, UID_ARG, UNBUFFERED_ARG, UNQUOTED_ARG, UUID_ARG, VERBOSE_ARG, VERSION_ARG, YES_ARG, NUM_SWITCHES }; typedef enum { DR_TASK = 1, DR_INFO = 2, DR_DEPS = 4, DR_TREE = 8, /* Complete dependency tree required */ DR_NAME = 16 } report_type_t; static int _switches[NUM_SWITCHES]; static int _int_args[NUM_SWITCHES]; static char *_string_args[NUM_SWITCHES]; static int _num_devices; static char *_uuid; static char *_table; static char *_target; static char *_command; static uint32_t _read_ahead_flags; static struct dm_tree *_dtree; static struct dm_report *_report; static report_type_t _report_type; /* * Commands */ typedef int (*command_fn) (int argc, char **argv, void *data); struct command { const char *name; const char *help; int min_args; int max_args; command_fn fn; }; static int _parse_line(struct dm_task *dmt, char *buffer, const char *file, int line) { char ttype[LINE_SIZE], *ptr, *comment; unsigned long long start, size; int n; /* trim trailing space */ for (ptr = buffer + strlen(buffer) - 1; ptr >= buffer; ptr--) if (!isspace((int) *ptr)) break; ptr++; *ptr = '\0'; /* trim leading space */ for (ptr = buffer; *ptr && isspace((int) *ptr); ptr++) ; if (!*ptr || *ptr == '#') return 1; if (sscanf(ptr, "%llu %llu %s %n", &start, &size, ttype, &n) < 3) { err("Invalid format on line %d of table %s", line, file); return 0; } ptr += n; if ((comment = strchr(ptr, (int) '#'))) *comment = '\0'; if (!dm_task_add_target(dmt, start, size, ttype, ptr)) return 0; return 1; } static int _parse_file(struct dm_task *dmt, const char *file) { char *buffer = NULL; size_t buffer_size = 0; FILE *fp; int r = 0, line = 0; /* one-line table on cmdline */ if (_table) return _parse_line(dmt, _table, "", ++line); /* OK for empty stdin */ if (file) { if (!(fp = fopen(file, "r"))) { err("Couldn't open '%s' for reading", file); return 0; } } else fp = stdin; #ifndef HAVE_GETLINE buffer_size = LINE_SIZE; if (!(buffer = dm_malloc(buffer_size))) { err("Failed to malloc line buffer."); return 0; } while (fgets(buffer, (int) buffer_size, fp)) #else while (getline(&buffer, &buffer_size, fp) > 0) #endif if (!_parse_line(dmt, buffer, file ? : "on stdin", ++line)) goto out; r = 1; out: #ifndef HAVE_GETLINE dm_free(buffer); #else free(buffer); #endif if (file && fclose(fp)) fprintf(stderr, "%s: fclose failed: %s", file, strerror(errno)); return r; } struct dm_split_name { char *subsystem; char *vg_name; char *lv_name; char *lv_layer; }; struct dmsetup_report_obj { struct dm_task *task; struct dm_info *info; struct dm_task *deps_task; struct dm_tree_node *tree_node; struct dm_split_name *split_name; }; static struct dm_task *_get_deps_task(int major, int minor) { struct dm_task *dmt; struct dm_info info; if (!(dmt = dm_task_create(DM_DEVICE_DEPS))) return NULL; if (!dm_task_set_major(dmt, major) || !dm_task_set_minor(dmt, minor)) goto err; if (_switches[NOOPENCOUNT_ARG] && !dm_task_no_open_count(dmt)) goto err; if (_switches[INACTIVE_ARG] && !dm_task_query_inactive_table(dmt)) goto err; if (!dm_task_run(dmt)) goto err; if (!dm_task_get_info(dmt, &info)) goto err; if (!info.exists) goto err; return dmt; err: dm_task_destroy(dmt); return NULL; } static char *_extract_uuid_prefix(const char *uuid, const int separator) { char *ptr = NULL; char *uuid_prefix = NULL; size_t len; if (uuid) ptr = strchr(uuid, separator); len = ptr ? ptr - uuid : 0; if (!(uuid_prefix = dm_malloc(len + 1))) { log_error("Failed to allocate memory to extract uuid prefix."); return NULL; } memcpy(uuid_prefix, uuid, len); uuid_prefix[len] = '\0'; return uuid_prefix; } static struct dm_split_name *_get_split_name(const char *uuid, const char *name, int separator) { struct dm_split_name *split_name; if (!(split_name = dm_malloc(sizeof(*split_name)))) { log_error("Failed to allocate memory to split device name " "into components."); return NULL; } split_name->subsystem = _extract_uuid_prefix(uuid, separator); split_name->vg_name = split_name->lv_name = split_name->lv_layer = (char *) ""; if (!strcmp(split_name->subsystem, "LVM") && (!(split_name->vg_name = dm_strdup(name)) || !dm_split_lvm_name(NULL, NULL, &split_name->vg_name, &split_name->lv_name, &split_name->lv_layer))) log_error("Failed to allocate memory to split LVM name " "into components."); return split_name; } static void _destroy_split_name(struct dm_split_name *split_name) { /* * lv_name and lv_layer are allocated within the same block * of memory as vg_name so don't need to be freed separately. */ if (!strcmp(split_name->subsystem, "LVM")) dm_free(split_name->vg_name); dm_free(split_name->subsystem); dm_free(split_name); } static int _display_info_cols(struct dm_task *dmt, struct dm_info *info) { struct dmsetup_report_obj obj; int r = 0; if (!info->exists) { fprintf(stderr, "Device does not exist.\n"); return 0; } obj.task = dmt; obj.info = info; obj.deps_task = NULL; obj.split_name = NULL; if (_report_type & DR_TREE) obj.tree_node = dm_tree_find_node(_dtree, info->major, info->minor); if (_report_type & DR_DEPS) obj.deps_task = _get_deps_task(info->major, info->minor); if (_report_type & DR_NAME) obj.split_name = _get_split_name(dm_task_get_uuid(dmt), dm_task_get_name(dmt), '-'); if (!dm_report_object(_report, &obj)) goto out; r = 1; out: if (obj.deps_task) dm_task_destroy(obj.deps_task); if (obj.split_name) _destroy_split_name(obj.split_name); return r; } static void _display_info_long(struct dm_task *dmt, struct dm_info *info) { const char *uuid; uint32_t read_ahead; if (!info->exists) { printf("Device does not exist.\n"); return; } printf("Name: %s\n", dm_task_get_name(dmt)); printf("State: %s%s\n", info->suspended ? "SUSPENDED" : "ACTIVE", info->read_only ? " (READ-ONLY)" : ""); /* FIXME Old value is being printed when it's being changed. */ if (dm_task_get_read_ahead(dmt, &read_ahead)) printf("Read Ahead: %" PRIu32 "\n", read_ahead); if (!info->live_table && !info->inactive_table) printf("Tables present: None\n"); else printf("Tables present: %s%s%s\n", info->live_table ? "LIVE" : "", info->live_table && info->inactive_table ? " & " : "", info->inactive_table ? "INACTIVE" : ""); if (info->open_count != -1) printf("Open count: %d\n", info->open_count); printf("Event number: %" PRIu32 "\n", info->event_nr); printf("Major, minor: %d, %d\n", info->major, info->minor); if (info->target_count != -1) printf("Number of targets: %d\n", info->target_count); if ((uuid = dm_task_get_uuid(dmt)) && *uuid) printf("UUID: %s\n", uuid); printf("\n"); } static int _display_info(struct dm_task *dmt) { struct dm_info info; if (!dm_task_get_info(dmt, &info)) return 0; if (!_switches[COLS_ARG]) _display_info_long(dmt, &info); else /* FIXME return code */ _display_info_cols(dmt, &info); return info.exists ? 1 : 0; } static int _set_task_device(struct dm_task *dmt, const char *name, int optional) { if (name) { if (!dm_task_set_name(dmt, name)) return 0; } else if (_switches[UUID_ARG]) { if (!dm_task_set_uuid(dmt, _uuid)) return 0; } else if (_switches[MAJOR_ARG] && _switches[MINOR_ARG]) { if (!dm_task_set_major(dmt, _int_args[MAJOR_ARG]) || !dm_task_set_minor(dmt, _int_args[MINOR_ARG])) return 0; } else if (!optional) { fprintf(stderr, "No device specified.\n"); return 0; } return 1; } static int _load(int argc, char **argv, void *data __attribute((unused))) { int r = 0; struct dm_task *dmt; const char *file = NULL; const char *name = NULL; if (_switches[NOTABLE_ARG]) { err("--notable only available when creating new device\n"); return 0; } if (!_switches[UUID_ARG] && !_switches[MAJOR_ARG]) { if (argc == 1) { err("Please specify device.\n"); return 0; } name = argv[1]; argc--; argv++; } else if (argc > 2) { err("Too many command line arguments.\n"); return 0; } if (argc == 2) file = argv[1]; if (!(dmt = dm_task_create(DM_DEVICE_RELOAD))) return 0; if (!_set_task_device(dmt, name, 0)) goto out; if (!_switches[NOTABLE_ARG] && !_parse_file(dmt, file)) goto out; if (_switches[READ_ONLY] && !dm_task_set_ro(dmt)) goto out; if (_switches[NOOPENCOUNT_ARG] && !dm_task_no_open_count(dmt)) goto out; if (_switches[INACTIVE_ARG] && !dm_task_query_inactive_table(dmt)) goto out; if (!dm_task_run(dmt)) goto out; r = 1; if (_switches[VERBOSE_ARG]) r = _display_info(dmt); out: dm_task_destroy(dmt); return r; } static int _create(int argc, char **argv, void *data __attribute((unused))) { int r = 0; struct dm_task *dmt; const char *file = NULL; uint32_t cookie = 0; if (argc == 3) file = argv[2]; if (!(dmt = dm_task_create(DM_DEVICE_CREATE))) return 0; if (!dm_task_set_name(dmt, argv[1])) goto out; if (_switches[UUID_ARG] && !dm_task_set_uuid(dmt, _uuid)) goto out; if (!_switches[NOTABLE_ARG] && !_parse_file(dmt, file)) goto out; if (_switches[READ_ONLY] && !dm_task_set_ro(dmt)) goto out; if (_switches[MAJOR_ARG] && !dm_task_set_major(dmt, _int_args[MAJOR_ARG])) goto out; if (_switches[MINOR_ARG] && !dm_task_set_minor(dmt, _int_args[MINOR_ARG])) goto out; if (_switches[UID_ARG] && !dm_task_set_uid(dmt, _int_args[UID_ARG])) goto out; if (_switches[GID_ARG] && !dm_task_set_gid(dmt, _int_args[GID_ARG])) goto out; if (_switches[MODE_ARG] && !dm_task_set_mode(dmt, _int_args[MODE_ARG])) goto out; if (_switches[NOOPENCOUNT_ARG] && !dm_task_no_open_count(dmt)) goto out; if (_switches[INACTIVE_ARG] && !dm_task_query_inactive_table(dmt)) goto out; if (_switches[READAHEAD_ARG] && !dm_task_set_read_ahead(dmt, _int_args[READAHEAD_ARG], _read_ahead_flags)) goto out; if (_switches[NOTABLE_ARG]) dm_udev_set_sync_support(0); if (!dm_task_set_cookie(dmt, &cookie, 0) || !dm_task_run(dmt)) goto out; r = 1; if (_switches[VERBOSE_ARG]) r = _display_info(dmt); out: (void) dm_udev_wait(cookie); dm_task_destroy(dmt); return r; } static int _rename(int argc, char **argv, void *data __attribute((unused))) { int r = 0; struct dm_task *dmt; uint32_t cookie = 0; if (!(dmt = dm_task_create(DM_DEVICE_RENAME))) return 0; /* FIXME Kernel doesn't support uuid or device number here yet */ if (!_set_task_device(dmt, (argc == 3) ? argv[1] : NULL, 0)) goto out; if (!dm_task_set_newname(dmt, argv[argc - 1])) goto out; if (_switches[NOOPENCOUNT_ARG] && !dm_task_no_open_count(dmt)) goto out; if (_switches[INACTIVE_ARG] && !dm_task_query_inactive_table(dmt)) goto out; if (!dm_task_set_cookie(dmt, &cookie, 0) || !dm_task_run(dmt)) goto out; r = 1; out: (void) dm_udev_wait(cookie); dm_task_destroy(dmt); return r; } static int _message(int argc, char **argv, void *data __attribute((unused))) { int r = 0, i; size_t sz = 1; struct dm_task *dmt; char *str; if (!(dmt = dm_task_create(DM_DEVICE_TARGET_MSG))) return 0; if (_switches[UUID_ARG] || _switches[MAJOR_ARG]) { if (!_set_task_device(dmt, NULL, 0)) goto out; } else { if (!_set_task_device(dmt, argv[1], 0)) goto out; argc--; argv++; } if (!dm_task_set_sector(dmt, (uint64_t) atoll(argv[1]))) goto out; argc -= 2; argv += 2; if (argc <= 0) err("No message supplied.\n"); for (i = 0; i < argc; i++) sz += strlen(argv[i]) + 1; if (!(str = dm_malloc(sz))) { err("message string allocation failed"); goto out; } memset(str, 0, sz); for (i = 0; i < argc; i++) { if (i) strcat(str, " "); strcat(str, argv[i]); } if (!dm_task_set_message(dmt, str)) goto out; dm_free(str); if (_switches[NOOPENCOUNT_ARG] && !dm_task_no_open_count(dmt)) goto out; if (_switches[INACTIVE_ARG] && !dm_task_query_inactive_table(dmt)) goto out; if (!dm_task_run(dmt)) goto out; r = 1; out: dm_task_destroy(dmt); return r; } static int _setgeometry(int argc, char **argv, void *data __attribute((unused))) { int r = 0; struct dm_task *dmt; if (!(dmt = dm_task_create(DM_DEVICE_SET_GEOMETRY))) return 0; if (_switches[UUID_ARG] || _switches[MAJOR_ARG]) { if (!_set_task_device(dmt, NULL, 0)) goto out; } else { if (!_set_task_device(dmt, argv[1], 0)) goto out; argc--; argv++; } if (!dm_task_set_geometry(dmt, argv[1], argv[2], argv[3], argv[4])) goto out; if (_switches[NOOPENCOUNT_ARG] && !dm_task_no_open_count(dmt)) goto out; if (_switches[INACTIVE_ARG] && !dm_task_query_inactive_table(dmt)) goto out; /* run the task */ if (!dm_task_run(dmt)) goto out; r = 1; out: dm_task_destroy(dmt); return r; } static int _splitname(int argc, char **argv, void *data __attribute((unused))) { struct dmsetup_report_obj obj; int r = 1; obj.task = NULL; obj.info = NULL; obj.deps_task = NULL; obj.tree_node = NULL; obj.split_name = _get_split_name((argc == 3) ? argv[2] : "LVM", argv[1], '\0'); r = dm_report_object(_report, &obj); _destroy_split_name(obj.split_name); return r; } static uint32_t _get_cookie_value(char *str_value) { unsigned long int value; char *p; if (!(value = strtoul(str_value, &p, 0)) || *p || (value == ULONG_MAX && errno == ERANGE) || value > 0xFFFFFFFF) { err("Incorrect cookie value"); return 0; } else return (uint32_t) value; } static int _udevflags(int args, char **argv, void *data __attribute((unused))) { uint32_t cookie; uint16_t flags; int i; static const char *dm_flag_names[] = {"DISABLE_DM_RULES", "DISABLE_SUBSYSTEM_RULES", "DISABLE_DISK_RULES", "DISABLE_OTHER_RULES", "LOW_PRIORITY", 0, 0, 0}; if (!(cookie = _get_cookie_value(argv[1]))) return 0; flags = cookie >> DM_UDEV_FLAGS_SHIFT; for (i = 0; i < DM_UDEV_FLAGS_SHIFT; i++) if (1 << i & flags) { if (i < DM_UDEV_FLAGS_SHIFT / 2 && dm_flag_names[i]) printf("DM_UDEV_%s_FLAG='1'\n", dm_flag_names[i]); else if (i < DM_UDEV_FLAGS_SHIFT / 2) /* * This is just a fallback. Each new DM flag * should have its symbolic name assigned. */ printf("DM_UDEV_FLAG%d='1'\n", i); else /* * We can't assign symbolic names to subsystem * flags. Their semantics vary based on the * subsystem that is currently used. */ printf("DM_SUBSYSTEM_UDEV_FLAG%d='1'\n", i - DM_UDEV_FLAGS_SHIFT / 2); } return 1; } static int _udevcomplete(int argc, char **argv, void *data __attribute((unused))) { uint32_t cookie; if (!(cookie = _get_cookie_value(argv[1]))) return 0; /* * Strip flags from the cookie and use cookie magic instead. * If the cookie has non-zero prefix and the base is zero then * this one carries flags to control udev rules only and it is * not meant to be for notification. Return with success in this * situation. */ if (!(cookie &= ~DM_UDEV_FLAGS_MASK)) return 1; cookie |= DM_COOKIE_MAGIC << DM_UDEV_FLAGS_SHIFT; return dm_udev_complete(cookie); } #ifndef UDEV_SYNC_SUPPORT static const char _cmd_not_supported[] = "Command not supported. Recompile with \"--enable-udev-sync\" to enable."; static int _udevcomplete_all(int argc __attribute((unused)), char **argv __attribute((unused)), void *data __attribute((unused))) { log_error(_cmd_not_supported); return 0; } static int _udevcookies(int argc __attribute((unused)), char **argv __attribute((unused)), void *data __attribute((unused))) { log_error(_cmd_not_supported); return 0; } #else /* UDEV_SYNC_SUPPORT */ static char _yes_no_prompt(const char *prompt, ...) { int c = 0, ret = 0; va_list ap; do { if (c == '\n' || !c) { va_start(ap, prompt); vprintf(prompt, ap); va_end(ap); } if ((c = getchar()) == EOF) { ret = 'n'; break; } c = tolower(c); if ((c == 'y') || (c == 'n')) ret = c; } while (!ret || c != '\n'); if (c != '\n') printf("\n"); return ret; } static int _udevcomplete_all(int argc __attribute((unused)), char **argv __attribute((unused)), void *data __attribute((unused))) { int max_id, id, sid; struct seminfo sinfo; struct semid_ds sdata; int counter = 0; if (!_switches[YES_ARG]) { log_warn("This operation will destroy all semaphores with keys " "that have a prefix %" PRIu16 " (0x%" PRIx16 ").", DM_COOKIE_MAGIC, DM_COOKIE_MAGIC); if (_yes_no_prompt("Do you really want to continue? [y/n]: ") == 'n') { log_print("Semaphores with keys prefixed by %" PRIu16 " (0x%" PRIx16 ") NOT destroyed.", DM_COOKIE_MAGIC, DM_COOKIE_MAGIC); return 1; } } if ((max_id = semctl(0, 0, SEM_INFO, &sinfo)) < 0) { log_sys_error("semctl", "SEM_INFO"); return 0; } for (id = 0; id <= max_id; id++) { if ((sid = semctl(id, 0, SEM_STAT, &sdata)) < 0) continue; if (sdata.sem_perm.__key >> 16 == DM_COOKIE_MAGIC) { if (semctl(sid, 0, IPC_RMID, 0) < 0) { log_error("Could not cleanup notification semaphore " "with semid %d and cookie value " "%" PRIu32 " (0x%" PRIx32 ")", sid, sdata.sem_perm.__key, sdata.sem_perm.__key); continue; } counter++; } } log_print("%d semaphores with keys prefixed by " "%" PRIu16 " (0x%" PRIx16 ") destroyed.", counter, DM_COOKIE_MAGIC, DM_COOKIE_MAGIC); return 1; } static int _udevcookies(int argc __attribute((unused)), char **argv __attribute((unused)), void *data __attribute((unused))) { int max_id, id, sid; struct seminfo sinfo; struct semid_ds sdata; int val; char *time_str; if ((max_id = semctl(0, 0, SEM_INFO, &sinfo)) < 0) { log_sys_error("sem_ctl", "SEM_INFO"); return 0; } printf("cookie semid value last_semop_time\n"); for (id = 0; id <= max_id; id++) { if ((sid = semctl(id, 0, SEM_STAT, &sdata)) < 0) continue; if (sdata.sem_perm.__key >> 16 == DM_COOKIE_MAGIC) { if ((val = semctl(sid, 0, GETVAL)) < 0) { log_error("semid %d: sem_ctl failed for " "cookie 0x%" PRIx32 ": %s", sid, sdata.sem_perm.__key, strerror(errno)); continue; } time_str = ctime((const time_t *) &sdata.sem_otime); printf("0x%-10x %-10d %-10d %s", sdata.sem_perm.__key, sid, val, time_str ? time_str : "unknown\n"); } } return 1; } #endif /* UDEV_SYNC_SUPPORT */ static int _version(int argc __attribute((unused)), char **argv __attribute((unused)), void *data __attribute((unused))) { char version[80]; if (dm_get_library_version(version, sizeof(version))) printf("Library version: %s\n", version); if (!dm_driver_version(version, sizeof(version))) return 0; printf("Driver version: %s\n", version); return 1; } static int _simple(int task, const char *name, uint32_t event_nr, int display) { uint32_t cookie = 0; int udev_wait_flag = task == DM_DEVICE_RESUME || task == DM_DEVICE_REMOVE; int r = 0; struct dm_task *dmt; if (!(dmt = dm_task_create(task))) return 0; if (!_set_task_device(dmt, name, 0)) goto out; if (event_nr && !dm_task_set_event_nr(dmt, event_nr)) goto out; if (_switches[NOFLUSH_ARG] && !dm_task_no_flush(dmt)) goto out; if (_switches[NOOPENCOUNT_ARG] && !dm_task_no_open_count(dmt)) goto out; if (_switches[INACTIVE_ARG] && !dm_task_query_inactive_table(dmt)) goto out; if (_switches[NOLOCKFS_ARG] && !dm_task_skip_lockfs(dmt)) goto out; if (_switches[READAHEAD_ARG] && !dm_task_set_read_ahead(dmt, _int_args[READAHEAD_ARG], _read_ahead_flags)) goto out; if (udev_wait_flag && !dm_task_set_cookie(dmt, &cookie, 0)) goto out; r = dm_task_run(dmt); if (r && display && _switches[VERBOSE_ARG]) r = _display_info(dmt); out: if (udev_wait_flag) (void) dm_udev_wait(cookie); dm_task_destroy(dmt); return r; } static int _suspend(int argc, char **argv, void *data __attribute((unused))) { return _simple(DM_DEVICE_SUSPEND, argc > 1 ? argv[1] : NULL, 0, 1); } static int _resume(int argc, char **argv, void *data __attribute((unused))) { return _simple(DM_DEVICE_RESUME, argc > 1 ? argv[1] : NULL, 0, 1); } static int _clear(int argc, char **argv, void *data __attribute((unused))) { return _simple(DM_DEVICE_CLEAR, argc > 1 ? argv[1] : NULL, 0, 1); } static int _wait(int argc, char **argv, void *data __attribute((unused))) { const char *name = NULL; if (!_switches[UUID_ARG] && !_switches[MAJOR_ARG]) { if (argc == 1) { err("No device specified."); return 0; } name = argv[1]; argc--, argv++; } return _simple(DM_DEVICE_WAITEVENT, name, (argc > 1) ? (uint32_t) atoi(argv[argc - 1]) : 0, 1); } static int _process_all(int argc, char **argv, int silent, int (*fn) (int argc, char **argv, void *data)) { int r = 1; struct dm_names *names; unsigned next = 0; struct dm_task *dmt; if (!(dmt = dm_task_create(DM_DEVICE_LIST))) return 0; if (!dm_task_run(dmt)) { r = 0; goto out; } if (!(names = dm_task_get_names(dmt))) { r = 0; goto out; } if (!names->dev) { if (!silent) printf("No devices found\n"); goto out; } do { names = (void *) names + next; if (!fn(argc, argv, (void *) names)) r = 0; next = names->next; } while (next); out: dm_task_destroy(dmt); return r; } static uint64_t _get_device_size(const char *name) { uint64_t start, length, size = UINT64_C(0); struct dm_info info; char *target_type, *params; struct dm_task *dmt; void *next = NULL; if (!(dmt = dm_task_create(DM_DEVICE_TABLE))) return 0; if (!_set_task_device(dmt, name, 0)) goto out; if (_switches[NOOPENCOUNT_ARG] && !dm_task_no_open_count(dmt)) goto out; if (_switches[INACTIVE_ARG] && !dm_task_query_inactive_table(dmt)) goto out; if (!dm_task_run(dmt)) goto out; if (!dm_task_get_info(dmt, &info) || !info.exists) goto out; do { next = dm_get_next_target(dmt, next, &start, &length, &target_type, ¶ms); size += length; } while (next); out: dm_task_destroy(dmt); return size; } static int _error_device(int argc __attribute((unused)), char **argv __attribute((unused)), void *data) { struct dm_names *names = (struct dm_names *) data; struct dm_task *dmt; const char *name; uint64_t size; int r = 0; if (data) name = names->name; else name = argv[1]; size = _get_device_size(name); if (!(dmt = dm_task_create(DM_DEVICE_RELOAD))) return 0; if (!_set_task_device(dmt, name, 0)) goto error; if (!dm_task_add_target(dmt, UINT64_C(0), size, "error", "")) goto error; if (_switches[READ_ONLY] && !dm_task_set_ro(dmt)) goto error; if (_switches[NOOPENCOUNT_ARG] && !dm_task_no_open_count(dmt)) goto error; if (_switches[INACTIVE_ARG] && !dm_task_query_inactive_table(dmt)) goto error; if (!dm_task_run(dmt)) goto error; if (!_simple(DM_DEVICE_RESUME, name, 0, 0)) { _simple(DM_DEVICE_CLEAR, name, 0, 0); goto error; } r = 1; error: dm_task_destroy(dmt); return r; } static int _remove(int argc, char **argv, void *data __attribute((unused))) { int r; if (_switches[FORCE_ARG] && argc > 1) r = _error_device(argc, argv, NULL); return _simple(DM_DEVICE_REMOVE, argc > 1 ? argv[1] : NULL, 0, 0); } static int _count_devices(int argc __attribute((unused)), char **argv __attribute((unused)), void *data __attribute((unused))) { _num_devices++; return 1; } static int _remove_all(int argc __attribute((unused)), char **argv __attribute((unused)), void *data __attribute((unused))) { int r; /* Remove all closed devices */ r = _simple(DM_DEVICE_REMOVE_ALL, "", 0, 0) | dm_mknodes(NULL); if (!_switches[FORCE_ARG]) return r; _num_devices = 0; r |= _process_all(argc, argv, 1, _count_devices); /* No devices left? */ if (!_num_devices) return r; r |= _process_all(argc, argv, 1, _error_device); r |= _simple(DM_DEVICE_REMOVE_ALL, "", 0, 0) | dm_mknodes(NULL); _num_devices = 0; r |= _process_all(argc, argv, 1, _count_devices); if (!_num_devices) return r; fprintf(stderr, "Unable to remove %d device(s).\n", _num_devices); return r; } static void _display_dev(struct dm_task *dmt, const char *name) { struct dm_info info; if (dm_task_get_info(dmt, &info)) printf("%s\t(%u, %u)\n", name, info.major, info.minor); } static int _mknodes(int argc, char **argv, void *data __attribute((unused))) { return dm_mknodes(argc > 1 ? argv[1] : NULL); } static int _exec_command(const char *name) { int n; static char path[PATH_MAX]; static char *args[ARGS_MAX + 1]; static int argc = 0; char *c; pid_t pid; if (argc < 0) return 0; if (!dm_mknodes(name)) return 0; n = snprintf(path, sizeof(path), "%s/%s", dm_dir(), name); if (n < 0 || n > (int) sizeof(path) - 1) return 0; if (!argc) { c = _command; while (argc < ARGS_MAX) { while (*c && isspace(*c)) c++; if (!*c) break; args[argc++] = c; while (*c && !isspace(*c)) c++; if (*c) *c++ = '\0'; } if (!argc) { argc = -1; return 0; } if (argc == ARGS_MAX) { err("Too many args to --exec\n"); argc = -1; return 0; } args[argc++] = path; args[argc] = NULL; } if (!(pid = fork())) { execvp(args[0], args); _exit(127); } else if (pid < (pid_t) 0) return 0; TEMP_FAILURE_RETRY(waitpid(pid, NULL, 0)); return 1; } static int _status(int argc, char **argv, void *data) { int r = 0; struct dm_task *dmt; void *next = NULL; uint64_t start, length; char *target_type = NULL; char *params, *c; int cmd; struct dm_names *names = (struct dm_names *) data; const char *name = NULL; int matched = 0; int ls_only = 0; struct dm_info info; if (data) name = names->name; else { if (argc == 1 && !_switches[UUID_ARG] && !_switches[MAJOR_ARG]) return _process_all(argc, argv, 0, _status); if (argc == 2) name = argv[1]; } if (!strcmp(argv[0], "table")) cmd = DM_DEVICE_TABLE; else cmd = DM_DEVICE_STATUS; if (!strcmp(argv[0], "ls")) ls_only = 1; if (!(dmt = dm_task_create(cmd))) return 0; if (!_set_task_device(dmt, name, 0)) goto out; if (_switches[NOOPENCOUNT_ARG] && !dm_task_no_open_count(dmt)) goto out; if (_switches[INACTIVE_ARG] && !dm_task_query_inactive_table(dmt)) goto out; if (!dm_task_run(dmt)) goto out; if (!dm_task_get_info(dmt, &info) || !info.exists) goto out; if (!name) name = dm_task_get_name(dmt); /* Fetch targets and print 'em */ do { next = dm_get_next_target(dmt, next, &start, &length, &target_type, ¶ms); /* Skip if target type doesn't match */ if (_switches[TARGET_ARG] && (!target_type || strcmp(target_type, _target))) continue; if (ls_only) { if (!_switches[EXEC_ARG] || !_command || _switches[VERBOSE_ARG]) _display_dev(dmt, name); next = NULL; } else if (!_switches[EXEC_ARG] || !_command || _switches[VERBOSE_ARG]) { if (!matched && _switches[VERBOSE_ARG]) _display_info(dmt); if (data && !_switches[VERBOSE_ARG]) printf("%s: ", name); if (target_type) { /* Suppress encryption key */ if (!_switches[SHOWKEYS_ARG] && cmd == DM_DEVICE_TABLE && !strcmp(target_type, "crypt")) { c = params; while (*c && *c != ' ') c++; if (*c) c++; while (*c && *c != ' ') *c++ = '0'; } printf("%" PRIu64 " %" PRIu64 " %s %s", start, length, target_type, params); } printf("\n"); } matched = 1; } while (next); if (data && _switches[VERBOSE_ARG] && matched && !ls_only) printf("\n"); if (matched && _switches[EXEC_ARG] && _command && !_exec_command(name)) goto out; r = 1; out: dm_task_destroy(dmt); return r; } /* Show target names and their version numbers */ static int _targets(int argc __attribute((unused)), char **argv __attribute((unused)), void *data __attribute((unused))) { int r = 0; struct dm_task *dmt; struct dm_versions *target; struct dm_versions *last_target; if (!(dmt = dm_task_create(DM_DEVICE_LIST_VERSIONS))) return 0; if (!dm_task_run(dmt)) goto out; target = dm_task_get_versions(dmt); /* Fetch targets and print 'em */ do { last_target = target; printf("%-16s v%d.%d.%d\n", target->name, target->version[0], target->version[1], target->version[2]); target = (void *) target + target->next; } while (last_target != target); r = 1; out: dm_task_destroy(dmt); return r; } static int _info(int argc, char **argv, void *data) { int r = 0; struct dm_task *dmt; struct dm_names *names = (struct dm_names *) data; char *name = NULL; if (data) name = names->name; else { if (argc == 1 && !_switches[UUID_ARG] && !_switches[MAJOR_ARG]) return _process_all(argc, argv, 0, _info); if (argc == 2) name = argv[1]; } if (!(dmt = dm_task_create(DM_DEVICE_INFO))) return 0; if (!_set_task_device(dmt, name, 0)) goto out; if (_switches[NOOPENCOUNT_ARG] && !dm_task_no_open_count(dmt)) goto out; if (_switches[INACTIVE_ARG] && !dm_task_query_inactive_table(dmt)) goto out; if (!dm_task_run(dmt)) goto out; r = _display_info(dmt); out: dm_task_destroy(dmt); return r; } static int _deps(int argc, char **argv, void *data) { int r = 0; uint32_t i; struct dm_deps *deps; struct dm_task *dmt; struct dm_info info; struct dm_names *names = (struct dm_names *) data; char *name = NULL; if (data) name = names->name; else { if (argc == 1 && !_switches[UUID_ARG] && !_switches[MAJOR_ARG]) return _process_all(argc, argv, 0, _deps); if (argc == 2) name = argv[1]; } if (!(dmt = dm_task_create(DM_DEVICE_DEPS))) return 0; if (!_set_task_device(dmt, name, 0)) goto out; if (_switches[NOOPENCOUNT_ARG] && !dm_task_no_open_count(dmt)) goto out; if (_switches[INACTIVE_ARG] && !dm_task_query_inactive_table(dmt)) goto out; if (!dm_task_run(dmt)) goto out; if (!dm_task_get_info(dmt, &info)) goto out; if (!(deps = dm_task_get_deps(dmt))) goto out; if (!info.exists) { printf("Device does not exist.\n"); r = 1; goto out; } if (_switches[VERBOSE_ARG]) _display_info(dmt); if (data && !_switches[VERBOSE_ARG]) printf("%s: ", name); printf("%d dependencies\t:", deps->count); for (i = 0; i < deps->count; i++) printf(" (%d, %d)", (int) MAJOR(deps->device[i]), (int) MINOR(deps->device[i])); printf("\n"); if (data && _switches[VERBOSE_ARG]) printf("\n"); r = 1; out: dm_task_destroy(dmt); return r; } static int _display_name(int argc __attribute((unused)), char **argv __attribute((unused)), void *data) { struct dm_names *names = (struct dm_names *) data; printf("%s\t(%d, %d)\n", names->name, (int) MAJOR(names->dev), (int) MINOR(names->dev)); return 1; } /* * Tree drawing code */ enum { TR_DEVICE=0, /* display device major:minor number */ TR_TABLE, TR_STATUS, TR_ACTIVE, TR_RW, TR_OPENCOUNT, TR_UUID, TR_COMPACT, TR_TRUNCATE, TR_BOTTOMUP, NUM_TREEMODE, }; static int _tree_switches[NUM_TREEMODE]; #define TR_PRINT_ATTRIBUTE ( _tree_switches[TR_ACTIVE] || \ _tree_switches[TR_RW] || \ _tree_switches[TR_OPENCOUNT] || \ _tree_switches[TR_UUID] ) #define TR_PRINT_TARGETS ( _tree_switches[TR_TABLE] || \ _tree_switches[TR_STATUS] ) /* Compact - fewer newlines */ #define TR_PRINT_COMPACT (_tree_switches[TR_COMPACT] && \ !TR_PRINT_ATTRIBUTE && \ !TR_PRINT_TARGETS) /* FIXME Get rid of this */ #define MAX_DEPTH 100 /* Drawing character definition from pstree */ /* [pstree comment] UTF-8 defines by Johan Myreen, updated by Ben Winslow */ #define UTF_V "\342\224\202" /* U+2502, Vertical line drawing char */ #define UTF_VR "\342\224\234" /* U+251C, Vertical and right */ #define UTF_H "\342\224\200" /* U+2500, Horizontal */ #define UTF_UR "\342\224\224" /* U+2514, Up and right */ #define UTF_HD "\342\224\254" /* U+252C, Horizontal and down */ #define VT_BEG "\033(0\017" /* use graphic chars */ #define VT_END "\033(B" /* back to normal char set */ #define VT_V "x" /* see UTF definitions above */ #define VT_VR "t" #define VT_H "q" #define VT_UR "m" #define VT_HD "w" static struct { const char *empty_2; /* */ const char *branch_2; /* |- */ const char *vert_2; /* | */ const char *last_2; /* `- */ const char *single_3; /* --- */ const char *first_3; /* -+- */ } _tsym_ascii = { " ", "|-", "| ", "`-", "---", "-+-" }, _tsym_utf = { " ", UTF_VR UTF_H, UTF_V " ", UTF_UR UTF_H, UTF_H UTF_H UTF_H, UTF_H UTF_HD UTF_H }, _tsym_vt100 = { " ", VT_BEG VT_VR VT_H VT_END, VT_BEG VT_V VT_END " ", VT_BEG VT_UR VT_H VT_END, VT_BEG VT_H VT_H VT_H VT_END, VT_BEG VT_H VT_HD VT_H VT_END }, *_tsym = &_tsym_ascii; /* * Tree drawing functions. */ /* FIXME Get rid of these statics - use dynamic struct */ /* FIXME Explain what these vars are for */ static int _tree_width[MAX_DEPTH], _tree_more[MAX_DEPTH]; static int _termwidth = 80; /* Maximum output width */ static int _cur_x = 1; /* Current horizontal output position */ static char _last_char = 0; static void _out_char(const unsigned c) { /* Only first UTF-8 char counts */ _cur_x += ((c & 0xc0) != 0x80); if (!_tree_switches[TR_TRUNCATE]) { putchar((int) c); return; } /* Truncation? */ if (_cur_x <= _termwidth) putchar((int) c); if (_cur_x == _termwidth + 1 && ((c & 0xc0) != 0x80)) { if (_last_char || (c & 0x80)) { putchar('.'); putchar('.'); putchar('.'); } else { _last_char = c; _cur_x--; } } } static void _out_string(const char *str) { while (*str) _out_char((unsigned char) *str++); } /* non-negative integers only */ static unsigned _out_int(unsigned num) { unsigned digits = 0; unsigned divi; if (!num) { _out_char('0'); return 1; } /* non zero case */ for (divi = 1; num / divi; divi *= 10) digits++; for (divi /= 10; divi; divi /= 10) _out_char('0' + (num / divi) % 10); return digits; } static void _out_newline(void) { if (_last_char && _cur_x == _termwidth) putchar(_last_char); _last_char = 0; putchar('\n'); _cur_x = 1; } static void _out_prefix(unsigned depth) { unsigned x, d; for (d = 0; d < depth; d++) { for (x = _tree_width[d] + 1; x > 0; x--) _out_char(' '); _out_string(d == depth - 1 ? !_tree_more[depth] ? _tsym->last_2 : _tsym->branch_2 : _tree_more[d + 1] ? _tsym->vert_2 : _tsym->empty_2); } } /* * Display tree */ static void _display_tree_attributes(struct dm_tree_node *node) { int attr = 0; const char *uuid; const struct dm_info *info; uuid = dm_tree_node_get_uuid(node); info = dm_tree_node_get_info(node); if (!info->exists) return; if (_tree_switches[TR_ACTIVE]) { _out_string(attr++ ? ", " : " ["); _out_string(info->suspended ? "SUSPENDED" : "ACTIVE"); } if (_tree_switches[TR_RW]) { _out_string(attr++ ? ", " : " ["); _out_string(info->read_only ? "RO" : "RW"); } if (_tree_switches[TR_OPENCOUNT]) { _out_string(attr++ ? ", " : " ["); (void) _out_int((unsigned) info->open_count); } if (_tree_switches[TR_UUID]) { _out_string(attr++ ? ", " : " ["); _out_string(uuid && *uuid ? uuid : ""); } if (attr) _out_char(']'); } static void _display_tree_node(struct dm_tree_node *node, unsigned depth, unsigned first_child __attribute((unused)), unsigned last_child, unsigned has_children) { int offset; const char *name; const struct dm_info *info; int first_on_line = 0; /* Sub-tree for targets has 2 more depth */ if (depth + 2 > MAX_DEPTH) return; name = dm_tree_node_get_name(node); if ((!name || !*name) && !_tree_switches[TR_DEVICE]) return; /* Indicate whether there are more nodes at this depth */ _tree_more[depth] = !last_child; _tree_width[depth] = 0; if (_cur_x == 1) first_on_line = 1; if (!TR_PRINT_COMPACT || first_on_line) _out_prefix(depth); /* Remember the starting point for compact */ offset = _cur_x; if (TR_PRINT_COMPACT && !first_on_line) _out_string(_tree_more[depth] ? _tsym->first_3 : _tsym->single_3); /* display node */ if (name) _out_string(name); info = dm_tree_node_get_info(node); if (_tree_switches[TR_DEVICE]) { _out_string(name ? " (" : "("); (void) _out_int(info->major); _out_char(':'); (void) _out_int(info->minor); _out_char(')'); } /* display additional info */ if (TR_PRINT_ATTRIBUTE) _display_tree_attributes(node); if (TR_PRINT_COMPACT) _tree_width[depth] = _cur_x - offset; if (!TR_PRINT_COMPACT || !has_children) _out_newline(); if (TR_PRINT_TARGETS) { _tree_more[depth + 1] = has_children; // FIXME _display_tree_targets(name, depth + 2); } } /* * Walk the dependency tree */ static void _display_tree_walk_children(struct dm_tree_node *node, unsigned depth) { struct dm_tree_node *child, *next_child; void *handle = NULL; uint32_t inverted = _tree_switches[TR_BOTTOMUP]; unsigned first_child = 1; unsigned has_children; next_child = dm_tree_next_child(&handle, node, inverted); while ((child = next_child)) { next_child = dm_tree_next_child(&handle, node, inverted); has_children = dm_tree_node_num_children(child, inverted) ? 1 : 0; _display_tree_node(child, depth, first_child, next_child ? 0U : 1U, has_children); if (has_children) _display_tree_walk_children(child, depth + 1); first_child = 0; } } static int _add_dep(int argc __attribute((unused)), char **argv __attribute((unused)), void *data) { struct dm_names *names = (struct dm_names *) data; if (!dm_tree_add_dev(_dtree, (unsigned) MAJOR(names->dev), (unsigned) MINOR(names->dev))) return 0; return 1; } /* * Create and walk dependency tree */ static int _build_whole_deptree(void) { if (_dtree) return 1; if (!(_dtree = dm_tree_create())) return 0; if (!_process_all(0, NULL, 0, _add_dep)) return 0; return 1; } static int _display_tree(int argc __attribute((unused)), char **argv __attribute((unused)), void *data __attribute((unused))) { if (!_build_whole_deptree()) return 0; _display_tree_walk_children(dm_tree_find_node(_dtree, 0, 0), 0); return 1; } /* * Report device information */ /* dm specific display functions */ static int _int32_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { const int32_t value = *(const int32_t *)data; return dm_report_field_int32(rh, field, &value); } static int _uint32_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { const uint32_t value = *(const int32_t *)data; return dm_report_field_uint32(rh, field, &value); } static int _dm_name_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { const char *name = dm_task_get_name((const struct dm_task *) data); return dm_report_field_string(rh, field, &name); } static int _dm_uuid_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { const char *uuid = dm_task_get_uuid((const struct dm_task *) data); if (!uuid || !*uuid) uuid = ""; return dm_report_field_string(rh, field, &uuid); } static int _dm_read_ahead_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { uint32_t value; if (!dm_task_get_read_ahead((const struct dm_task *) data, &value)) value = 0; return dm_report_field_uint32(rh, field, &value); } static int _dm_info_status_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { char buf[5]; const char *s = buf; const struct dm_info *info = data; buf[0] = info->live_table ? 'L' : '-'; buf[1] = info->inactive_table ? 'I' : '-'; buf[2] = info->suspended ? 's' : '-'; buf[3] = info->read_only ? 'r' : 'w'; buf[4] = '\0'; return dm_report_field_string(rh, field, &s); } static int _dm_info_table_loaded_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { const struct dm_info *info = data; if (info->live_table) { if (info->inactive_table) dm_report_field_set_value(field, "Both", NULL); else dm_report_field_set_value(field, "Live", NULL); return 1; } if (info->inactive_table) dm_report_field_set_value(field, "Inactive", NULL); else dm_report_field_set_value(field, "None", NULL); return 1; } static int _dm_info_suspended_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { const struct dm_info *info = data; if (info->suspended) dm_report_field_set_value(field, "Suspended", NULL); else dm_report_field_set_value(field, "Active", NULL); return 1; } static int _dm_info_read_only_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { const struct dm_info *info = data; if (info->read_only) dm_report_field_set_value(field, "Read-only", NULL); else dm_report_field_set_value(field, "Writeable", NULL); return 1; } static int _dm_info_devno_disp(struct dm_report *rh, struct dm_pool *mem, struct dm_report_field *field, const void *data, void *private) { char buf[DM_MAX_TYPE_NAME], *repstr; struct dm_info *info = (struct dm_info *) data; if (!dm_pool_begin_object(mem, 8)) { log_error("dm_pool_begin_object failed"); return 0; } if (dm_snprintf(buf, sizeof(buf), "%d:%d", info->major, info->minor) < 0) { log_error("dm_pool_alloc failed"); goto out_abandon; } if (!dm_pool_grow_object(mem, buf, strlen(buf) + 1)) { log_error("dm_pool_grow_object failed"); goto out_abandon; } repstr = dm_pool_end_object(mem); dm_report_field_set_value(field, repstr, repstr); return 1; out_abandon: dm_pool_abandon_object(mem); return 0; } static int _dm_tree_names(struct dm_report *rh, struct dm_pool *mem, struct dm_report_field *field, const void *data, void *private, unsigned inverted) { struct dm_tree_node *node = (struct dm_tree_node *) data, *parent; void *t = NULL; const char *name; int first_node = 1; char *repstr; if (!dm_pool_begin_object(mem, 16)) { log_error("dm_pool_begin_object failed"); return 0; } while ((parent = dm_tree_next_child(&t, node, inverted))) { name = dm_tree_node_get_name(parent); if (!name || !*name) continue; if (!first_node && !dm_pool_grow_object(mem, ",", 1)) { log_error("dm_pool_grow_object failed"); goto out_abandon; } if (!dm_pool_grow_object(mem, name, 0)) { log_error("dm_pool_grow_object failed"); goto out_abandon; } if (first_node) first_node = 0; } if (!dm_pool_grow_object(mem, "\0", 1)) { log_error("dm_pool_grow_object failed"); goto out_abandon; } repstr = dm_pool_end_object(mem); dm_report_field_set_value(field, repstr, repstr); return 1; out_abandon: dm_pool_abandon_object(mem); return 0; } static int _dm_deps_names_disp(struct dm_report *rh, struct dm_pool *mem, struct dm_report_field *field, const void *data, void *private) { return _dm_tree_names(rh, mem, field, data, private, 0); } static int _dm_tree_parents_names_disp(struct dm_report *rh, struct dm_pool *mem, struct dm_report_field *field, const void *data, void *private) { return _dm_tree_names(rh, mem, field, data, private, 1); } static int _dm_tree_parents_devs_disp(struct dm_report *rh, struct dm_pool *mem, struct dm_report_field *field, const void *data, void *private) { struct dm_tree_node *node = (struct dm_tree_node *) data, *parent; void *t = NULL; const struct dm_info *info; int first_node = 1; char buf[DM_MAX_TYPE_NAME], *repstr; if (!dm_pool_begin_object(mem, 16)) { log_error("dm_pool_begin_object failed"); return 0; } while ((parent = dm_tree_next_child(&t, node, 1))) { info = dm_tree_node_get_info(parent); if (!info->major && !info->minor) continue; if (!first_node && !dm_pool_grow_object(mem, ",", 1)) { log_error("dm_pool_grow_object failed"); goto out_abandon; } if (dm_snprintf(buf, sizeof(buf), "%d:%d", info->major, info->minor) < 0) { log_error("dm_snprintf failed"); goto out_abandon; } if (!dm_pool_grow_object(mem, buf, 0)) { log_error("dm_pool_grow_object failed"); goto out_abandon; } if (first_node) first_node = 0; } if (!dm_pool_grow_object(mem, "\0", 1)) { log_error("dm_pool_grow_object failed"); goto out_abandon; } repstr = dm_pool_end_object(mem); dm_report_field_set_value(field, repstr, repstr); return 1; out_abandon: dm_pool_abandon_object(mem); return 0; } static int _dm_tree_parents_count_disp(struct dm_report *rh, struct dm_pool *mem, struct dm_report_field *field, const void *data, void *private) { struct dm_tree_node *node = (struct dm_tree_node *) data; int num_parent = dm_tree_node_num_children(node, 1); return dm_report_field_int(rh, field, &num_parent); } static int _dm_deps_disp(struct dm_report *rh, struct dm_pool *mem, struct dm_report_field *field, const void *data, void *private) { struct dm_deps *deps = (struct dm_deps *) data; int i; char buf[DM_MAX_TYPE_NAME], *repstr; if (!dm_pool_begin_object(mem, 16)) { log_error("dm_pool_begin_object failed"); return 0; } for (i = 0; i < deps->count; i++) { if (dm_snprintf(buf, sizeof(buf), "%d:%d", (int) MAJOR(deps->device[i]), (int) MINOR(deps->device[i])) < 0) { log_error("dm_snprintf failed"); goto out_abandon; } if (!dm_pool_grow_object(mem, buf, 0)) { log_error("dm_pool_grow_object failed"); goto out_abandon; } if (i + 1 < deps->count && !dm_pool_grow_object(mem, ",", 1)) { log_error("dm_pool_grow_object failed"); goto out_abandon; } } if (!dm_pool_grow_object(mem, "\0", 1)) { log_error("dm_pool_grow_object failed"); goto out_abandon; } repstr = dm_pool_end_object(mem); dm_report_field_set_value(field, repstr, repstr); return 1; out_abandon: dm_pool_abandon_object(mem); return 0; } static int _dm_subsystem_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { return dm_report_field_string(rh, field, (const char **) data); } static int _dm_vg_name_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { return dm_report_field_string(rh, field, (const char **) data); } static int _dm_lv_name_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { return dm_report_field_string(rh, field, (const char **) data); } static int _dm_lv_layer_name_disp(struct dm_report *rh, struct dm_pool *mem __attribute((unused)), struct dm_report_field *field, const void *data, void *private __attribute((unused))) { return dm_report_field_string(rh, field, (const char **) data); } static void *_task_get_obj(void *obj) { return ((struct dmsetup_report_obj *)obj)->task; } static void *_info_get_obj(void *obj) { return ((struct dmsetup_report_obj *)obj)->info; } static void *_deps_get_obj(void *obj) { return dm_task_get_deps(((struct dmsetup_report_obj *)obj)->deps_task); } static void *_tree_get_obj(void *obj) { return ((struct dmsetup_report_obj *)obj)->tree_node; } static void *_split_name_get_obj(void *obj) { return ((struct dmsetup_report_obj *)obj)->split_name; } static const struct dm_report_object_type _report_types[] = { { DR_TASK, "Mapped Device Name", "", _task_get_obj }, { DR_INFO, "Mapped Device Information", "", _info_get_obj }, { DR_DEPS, "Mapped Device Relationship Information", "", _deps_get_obj }, { DR_TREE, "Mapped Device Relationship Information", "", _tree_get_obj }, { DR_NAME, "Mapped Device Name Components", "", _split_name_get_obj }, { 0, "", "", NULL }, }; /* Column definitions */ #define OFFSET_OF(strct, field) (((char*)&((struct strct*)0)->field) - (char*)0) #define STR (DM_REPORT_FIELD_TYPE_STRING) #define NUM (DM_REPORT_FIELD_TYPE_NUMBER) #define FIELD_O(type, strct, sorttype, head, field, width, func, id, desc) {DR_ ## type, sorttype, OFFSET_OF(strct, field), width, id, head, &_ ## func ## _disp, desc}, #define FIELD_F(type, sorttype, head, width, func, id, desc) {DR_ ## type, sorttype, 0, width, id, head, &_ ## func ## _disp, desc}, static const struct dm_report_field_type _report_fields[] = { /* *INDENT-OFF* */ FIELD_F(TASK, STR, "Name", 16, dm_name, "name", "Name of mapped device.") FIELD_F(TASK, STR, "UUID", 32, dm_uuid, "uuid", "Unique (optional) identifier for mapped device.") /* FIXME Next one should be INFO */ FIELD_F(TASK, NUM, "RAhead", 6, dm_read_ahead, "read_ahead", "Read ahead in sectors.") FIELD_F(INFO, STR, "Stat", 4, dm_info_status, "attr", "(L)ive, (I)nactive, (s)uspended, (r)ead-only, read-(w)rite.") FIELD_F(INFO, STR, "Tables", 6, dm_info_table_loaded, "tables_loaded", "Which of the live and inactive table slots are filled.") FIELD_F(INFO, STR, "Suspended", 9, dm_info_suspended, "suspended", "Whether the device is suspended.") FIELD_F(INFO, STR, "Read-only", 9, dm_info_read_only, "readonly", "Whether the device is read-only or writeable.") FIELD_F(INFO, STR, "DevNo", 5, dm_info_devno, "devno", "Device major and minor numbers") FIELD_O(INFO, dm_info, NUM, "Maj", major, 3, int32, "major", "Block device major number.") FIELD_O(INFO, dm_info, NUM, "Min", minor, 3, int32, "minor", "Block device minor number.") FIELD_O(INFO, dm_info, NUM, "Open", open_count, 4, int32, "open", "Number of references to open device, if requested.") FIELD_O(INFO, dm_info, NUM, "Targ", target_count, 4, int32, "segments", "Number of segments in live table, if present.") FIELD_O(INFO, dm_info, NUM, "Event", event_nr, 6, uint32, "events", "Number of most recent event.") FIELD_O(DEPS, dm_deps, NUM, "#Devs", count, 5, int32, "device_count", "Number of devices used by this one.") FIELD_F(TREE, STR, "DevNames", 8, dm_deps_names, "devs_used", "List of names of mapped devices used by this one.") FIELD_F(DEPS, STR, "DevNos", 6, dm_deps, "devnos_used", "List of device numbers of devices used by this one.") FIELD_F(TREE, NUM, "#Refs", 5, dm_tree_parents_count, "device_ref_count", "Number of mapped devices referencing this one.") FIELD_F(TREE, STR, "RefNames", 8, dm_tree_parents_names, "names_using_dev", "List of names of mapped devices using this one.") FIELD_F(TREE, STR, "RefDevNos", 9, dm_tree_parents_devs, "devnos_using_dev", "List of device numbers of mapped devices using this one.") FIELD_O(NAME, dm_split_name, STR, "Subsys", subsystem, 6, dm_subsystem, "subsystem", "Userspace subsystem responsible for this device.") FIELD_O(NAME, dm_split_name, STR, "VG", vg_name, 4, dm_vg_name, "vg_name", "LVM Volume Group name.") FIELD_O(NAME, dm_split_name, STR, "LV", lv_name, 4, dm_lv_name, "lv_name", "LVM Logical Volume name.") FIELD_O(NAME, dm_split_name, STR, "LVLayer", lv_layer, 7, dm_lv_layer_name, "lv_layer", "LVM device layer.") {0, 0, 0, 0, "", "", NULL, NULL}, /* *INDENT-ON* */ }; #undef STR #undef NUM #undef FIELD_O #undef FIELD_F static const char *default_report_options = "name,major,minor,attr,open,segments,events,uuid"; static const char *splitname_report_options = "vg_name,lv_name,lv_layer"; static int _report_init(struct command *c) { char *options = (char *) default_report_options; const char *keys = ""; const char *separator = " "; int aligned = 1, headings = 1, buffered = 1, field_prefixes = 0; int quoted = 1, columns_as_rows = 0; uint32_t flags = 0; size_t len = 0; int r = 0; if (!strcmp(c->name, "splitname")) options = (char *) splitname_report_options; /* emulate old dmsetup behaviour */ if (_switches[NOHEADINGS_ARG]) { separator = ":"; aligned = 0; headings = 0; } if (_switches[UNBUFFERED_ARG]) buffered = 0; if (_switches[ROWS_ARG]) columns_as_rows = 1; if (_switches[UNQUOTED_ARG]) quoted = 0; if (_switches[NAMEPREFIXES_ARG]) { aligned = 0; field_prefixes = 1; } if (_switches[OPTIONS_ARG] && _string_args[OPTIONS_ARG]) { if (*_string_args[OPTIONS_ARG] != '+') options = _string_args[OPTIONS_ARG]; else { len = strlen(default_report_options) + strlen(_string_args[OPTIONS_ARG]) + 1; if (!(options = dm_malloc(len))) { err("Failed to allocate option string."); return 0; } if (dm_snprintf(options, len, "%s,%s", default_report_options, &_string_args[OPTIONS_ARG][1]) < 0) { err("snprintf failed"); goto out; } } } if (_switches[SORT_ARG] && _string_args[SORT_ARG]) { keys = _string_args[SORT_ARG]; buffered = 1; if (c && (!strcmp(c->name, "status") || !strcmp(c->name, "table"))) { err("--sort is not yet supported with status and table"); goto out; } } if (_switches[SEPARATOR_ARG] && _string_args[SEPARATOR_ARG]) { separator = _string_args[SEPARATOR_ARG]; aligned = 0; } if (aligned) flags |= DM_REPORT_OUTPUT_ALIGNED; if (buffered) flags |= DM_REPORT_OUTPUT_BUFFERED; if (headings) flags |= DM_REPORT_OUTPUT_HEADINGS; if (field_prefixes) flags |= DM_REPORT_OUTPUT_FIELD_NAME_PREFIX; if (!quoted) flags |= DM_REPORT_OUTPUT_FIELD_UNQUOTED; if (columns_as_rows) flags |= DM_REPORT_OUTPUT_COLUMNS_AS_ROWS; if (!(_report = dm_report_init(&_report_type, _report_types, _report_fields, options, separator, flags, keys, NULL))) goto out; if ((_report_type & DR_TREE) && !_build_whole_deptree()) { err("Internal device dependency tree creation failed."); goto out; } if (field_prefixes) dm_report_set_output_field_name_prefix(_report, "dm_"); r = 1; out: if (len) dm_free(options); return r; } /* * List devices */ static int _ls(int argc, char **argv, void *data) { if ((_switches[TARGET_ARG] && _target) || (_switches[EXEC_ARG] && _command)) return _status(argc, argv, data); else if ((_switches[TREE_ARG])) return _display_tree(argc, argv, data); else return _process_all(argc, argv, 0, _display_name); } static int _help(int argc, char **argv, void *data); /* * Dispatch table */ static struct command _commands[] = { {"help", "[-c|-C|--columns]", 0, 0, _help}, {"create", " [-j|--major -m|--minor ]\n" "\t [-U|--uid ] [-G|--gid ] [-M|--mode ]\n" "\t [-u|uuid ]\n" "\t [--notable | --table | ]", 1, 2, _create}, {"remove", "[-f|--force] ", 0, 1, _remove}, {"remove_all", "[-f|--force]", 0, 0, _remove_all}, {"suspend", "[--noflush] ", 0, 1, _suspend}, {"resume", "", 0, 1, _resume}, {"load", " []", 0, 2, _load}, {"clear", "", 0, 1, _clear}, {"reload", " []", 0, 2, _load}, {"rename", " ", 1, 2, _rename}, {"message", " ", 2, -1, _message}, {"ls", "[--target ] [--exec ] [--tree [-o options]]", 0, 0, _ls}, {"info", "[]", 0, 1, _info}, {"deps", "[]", 0, 1, _deps}, {"status", "[] [--target ]", 0, 1, _status}, {"table", "[] [--target ] [--showkeys]", 0, 1, _status}, {"wait", " []", 0, 2, _wait}, {"mknodes", "[]", 0, 1, _mknodes}, {"udevflags", "", 1, 1, _udevflags}, {"udevcomplete", "", 1, 1, _udevcomplete}, {"udevcomplete_all", "", 0, 0, _udevcomplete_all}, {"udevcookies", "", 0, 0, _udevcookies}, {"targets", "", 0, 0, _targets}, {"version", "", 0, 0, _version}, {"setgeometry", " ", 5, 5, _setgeometry}, {"splitname", " []", 1, 2, _splitname}, {NULL, NULL, 0, 0, NULL} }; static void _usage(FILE *out) { int i; fprintf(out, "Usage:\n\n"); fprintf(out, "dmsetup [--version] [-v|--verbose [-v|--verbose ...]]\n" " [-r|--readonly] [--noopencount] [--nolockfs] [--inactive]\n" " [--noudevsync] [-y|--yes] [--readahead [+]|auto|none]\n" " [-c|-C|--columns] [-o ] [-O|--sort ]\n" " [--nameprefixes] [--noheadings] [--separator ]\n\n"); for (i = 0; _commands[i].name; i++) fprintf(out, "\t%s %s\n", _commands[i].name, _commands[i].help); fprintf(out, "\n may be device name or -u or " "-j -m \n"); fprintf(out, " are comma-separated. Use 'help -c' for list.\n"); fprintf(out, "Table_file contents may be supplied on stdin.\n"); fprintf(out, "Tree options are: ascii, utf, vt100; compact, inverted, notrunc;\n" " [no]device, active, open, rw and uuid.\n"); fprintf(out, "\n"); return; } static void _losetup_usage(FILE *out) { fprintf(out, "Usage:\n\n"); fprintf(out, "losetup [-d|-a] [-e encryption] " "[-o offset] [-f|loop_device] [file]\n\n"); } static int _help(int argc __attribute((unused)), char **argv __attribute((unused)), void *data __attribute((unused))) { _usage(stderr); if (_switches[COLS_ARG]) { _switches[OPTIONS_ARG] = 1; _string_args[OPTIONS_ARG] = (char *) "help"; _switches[SORT_ARG] = 0; (void) _report_init(NULL); } return 1; } static struct command *_find_command(const char *name) { int i; for (i = 0; _commands[i].name; i++) if (!strcmp(_commands[i].name, name)) return _commands + i; return NULL; } static int _process_tree_options(const char *options) { const char *s, *end; struct winsize winsz; size_t len; /* Symbol set default */ if (!strcmp(nl_langinfo(CODESET), "UTF-8")) _tsym = &_tsym_utf; else _tsym = &_tsym_ascii; /* Default */ _tree_switches[TR_DEVICE] = 1; _tree_switches[TR_TRUNCATE] = 1; /* parse */ for (s = options; s && *s; s++) { len = 0; for (end = s; *end && *end != ','; end++, len++) ; if (!strncmp(s, "device", len)) _tree_switches[TR_DEVICE] = 1; else if (!strncmp(s, "nodevice", len)) _tree_switches[TR_DEVICE] = 0; else if (!strncmp(s, "status", len)) _tree_switches[TR_STATUS] = 1; else if (!strncmp(s, "table", len)) _tree_switches[TR_TABLE] = 1; else if (!strncmp(s, "active", len)) _tree_switches[TR_ACTIVE] = 1; else if (!strncmp(s, "open", len)) _tree_switches[TR_OPENCOUNT] = 1; else if (!strncmp(s, "uuid", len)) _tree_switches[TR_UUID] = 1; else if (!strncmp(s, "rw", len)) _tree_switches[TR_RW] = 1; else if (!strncmp(s, "utf", len)) _tsym = &_tsym_utf; else if (!strncmp(s, "vt100", len)) _tsym = &_tsym_vt100; else if (!strncmp(s, "ascii", len)) _tsym = &_tsym_ascii; else if (!strncmp(s, "inverted", len)) _tree_switches[TR_BOTTOMUP] = 1; else if (!strncmp(s, "compact", len)) _tree_switches[TR_COMPACT] = 1; else if (!strncmp(s, "notrunc", len)) _tree_switches[TR_TRUNCATE] = 0; else { fprintf(stderr, "Tree options not recognised: %s\n", s); return 0; } if (!*end) break; s = end; } /* Truncation doesn't work well with vt100 drawing char */ if (_tsym != &_tsym_vt100) if (ioctl(1, (unsigned long) TIOCGWINSZ, &winsz) >= 0 && winsz.ws_col > 3) _termwidth = winsz.ws_col - 3; return 1; } /* * Returns the full absolute path, or NULL if the path could * not be resolved. */ static char *_get_abspath(const char *path) { char *_path; #ifdef HAVE_CANONICALIZE_FILE_NAME _path = canonicalize_file_name(path); #else /* FIXME Provide alternative */ #endif return _path; } static char *parse_loop_device_name(const char *dev, const char *dev_dir) { char *buf; char *device; if (!(buf = dm_malloc(PATH_MAX))) return NULL; if (dev[0] == '/') { if (!(device = _get_abspath(dev))) goto error; if (strncmp(device, dev_dir, strlen(dev_dir))) goto error; /* If dev_dir does not end in a slash, ensure that the following byte in the device string is "/". */ if (dev_dir[strlen(dev_dir) - 1] != '/' && device[strlen(dev_dir)] != '/') goto error; strncpy(buf, strrchr(device, '/') + 1, (size_t) PATH_MAX); dm_free(device); } else { /* check for device number */ if (!strncmp(dev, "loop", strlen("loop"))) strncpy(buf, dev, (size_t) PATH_MAX); else goto error; } return buf; error: return NULL; } /* * create a table for a mapped device using the loop target. */ static int _loop_table(char *table, size_t tlen, char *file, char *dev __attribute((unused)), off_t off) { struct stat fbuf; off_t size, sectors; int fd = -1; #ifdef HAVE_SYS_STATVFS_H struct statvfs fsbuf; off_t blksize; #endif if (!_switches[READ_ONLY]) fd = open(file, O_RDWR); if (fd < 0) { _switches[READ_ONLY]++; fd = open(file, O_RDONLY); } if (fd < 0) goto error; if (fstat(fd, &fbuf)) goto error; size = (fbuf.st_size - off); sectors = size >> SECTOR_SHIFT; if (_switches[VERBOSE_ARG]) fprintf(stderr, "losetup: set loop size to %llukB " "(%llu sectors)\n", (long long unsigned) sectors >> 1, (long long unsigned) sectors); #ifdef HAVE_SYS_STATVFS_H if (fstatvfs(fd, &fsbuf)) goto error; /* FIXME Fragment size currently unused */ blksize = fsbuf.f_frsize; #endif close(fd); if (dm_snprintf(table, tlen, "%llu %llu loop %s %llu\n", 0ULL, (long long unsigned)sectors, file, off) < 0) return 0; if (_switches[VERBOSE_ARG] > 1) fprintf(stderr, "Table: %s\n", table); return 1; error: if (fd > -1) close(fd); return 0; } static int _process_losetup_switches(const char *base, int *argc, char ***argv, const char *dev_dir) { static int ind; int c; int encrypt_loop = 0, delete = 0, find = 0, show_all = 0; char *device_name = NULL; char *loop_file = NULL; off_t offset = 0; #ifdef HAVE_GETOPTLONG static struct option long_options[] = { {0, 0, 0, 0} }; #endif optarg = 0; optind = OPTIND_INIT; while ((ind = -1, c = GETOPTLONG_FN(*argc, *argv, "ade:fo:v", long_options, NULL)) != -1 ) { if (c == ':' || c == '?') return 0; if (c == 'a') show_all++; if (c == 'd') delete++; if (c == 'e') encrypt_loop++; if (c == 'f') find++; if (c == 'o') offset = atoi(optarg); if (c == 'v') _switches[VERBOSE_ARG]++; } *argv += optind ; *argc -= optind ; if (encrypt_loop){ fprintf(stderr, "%s: Sorry, cryptoloop is not yet implemented " "in this version.\n", base); return 0; } if (show_all) { fprintf(stderr, "%s: Sorry, show all is not yet implemented " "in this version.\n", base); return 0; } if (find) { fprintf(stderr, "%s: Sorry, find is not yet implemented " "in this version.\n", base); if (!*argc) return 0; } if (!*argc) { fprintf(stderr, "%s: Please specify loop_device.\n", base); _losetup_usage(stderr); return 0; } if (!(device_name = parse_loop_device_name((*argv)[0], dev_dir))) { fprintf(stderr, "%s: Could not parse loop_device %s\n", base, (*argv)[0]); _losetup_usage(stderr); return 0; } if (delete) { *argc = 2; (*argv)[1] = device_name; (*argv)[0] = (char *) "remove"; return 1; } if (*argc != 2) { fprintf(stderr, "%s: Too few arguments\n", base); _losetup_usage(stderr); dm_free(device_name); return 0; } /* FIXME move these to make them available to native dmsetup */ if (!(loop_file = _get_abspath((*argv)[(find) ? 0 : 1]))) { fprintf(stderr, "%s: Could not parse loop file name %s\n", base, (*argv)[1]); _losetup_usage(stderr); dm_free(device_name); return 0; } /* FIXME Missing free */ _table = dm_malloc(LOOP_TABLE_SIZE); if (!_loop_table(_table, (size_t) LOOP_TABLE_SIZE, loop_file, device_name, offset)) { fprintf(stderr, "Could not build device-mapper table for %s\n", (*argv)[0]); dm_free(device_name); return 0; } _switches[TABLE_ARG]++; (*argv)[0] = (char *) "create"; (*argv)[1] = device_name ; return 1; } static int _process_switches(int *argc, char ***argv, const char *dev_dir) { char *base, *namebase, *s; static int ind; int c, r; #ifdef HAVE_GETOPTLONG static struct option long_options[] = { {"readonly", 0, &ind, READ_ONLY}, {"columns", 0, &ind, COLS_ARG}, {"exec", 1, &ind, EXEC_ARG}, {"force", 0, &ind, FORCE_ARG}, {"gid", 1, &ind, GID_ARG}, {"inactive", 0, &ind, INACTIVE_ARG}, {"major", 1, &ind, MAJOR_ARG}, {"minor", 1, &ind, MINOR_ARG}, {"mode", 1, &ind, MODE_ARG}, {"nameprefixes", 0, &ind, NAMEPREFIXES_ARG}, {"noflush", 0, &ind, NOFLUSH_ARG}, {"noheadings", 0, &ind, NOHEADINGS_ARG}, {"nolockfs", 0, &ind, NOLOCKFS_ARG}, {"noopencount", 0, &ind, NOOPENCOUNT_ARG}, {"notable", 0, &ind, NOTABLE_ARG}, {"noudevsync", 0, &ind, NOUDEVSYNC_ARG}, {"options", 1, &ind, OPTIONS_ARG}, {"readahead", 1, &ind, READAHEAD_ARG}, {"rows", 0, &ind, ROWS_ARG}, {"separator", 1, &ind, SEPARATOR_ARG}, {"showkeys", 0, &ind, SHOWKEYS_ARG}, {"sort", 1, &ind, SORT_ARG}, {"table", 1, &ind, TABLE_ARG}, {"target", 1, &ind, TARGET_ARG}, {"tree", 0, &ind, TREE_ARG}, {"uid", 1, &ind, UID_ARG}, {"uuid", 1, &ind, UUID_ARG}, {"unbuffered", 0, &ind, UNBUFFERED_ARG}, {"unquoted", 0, &ind, UNQUOTED_ARG}, {"verbose", 1, &ind, VERBOSE_ARG}, {"version", 0, &ind, VERSION_ARG}, {"yes", 0, &ind, YES_ARG}, {0, 0, 0, 0} }; #else struct option long_options; #endif /* * Zero all the index counts. */ memset(&_switches, 0, sizeof(_switches)); memset(&_int_args, 0, sizeof(_int_args)); _read_ahead_flags = 0; namebase = strdup((*argv)[0]); base = basename(namebase); if (!strcmp(base, "devmap_name")) { free(namebase); _switches[COLS_ARG]++; _switches[NOHEADINGS_ARG]++; _switches[OPTIONS_ARG]++; _switches[MAJOR_ARG]++; _switches[MINOR_ARG]++; _string_args[OPTIONS_ARG] = (char *) "name"; if (*argc == 3) { _int_args[MAJOR_ARG] = atoi((*argv)[1]); _int_args[MINOR_ARG] = atoi((*argv)[2]); *argc -= 2; *argv += 2; } else if ((*argc == 2) && (2 == sscanf((*argv)[1], "%i:%i", &_int_args[MAJOR_ARG], &_int_args[MINOR_ARG]))) { *argc -= 1; *argv += 1; } else { fprintf(stderr, "Usage: devmap_name \n"); return 0; } (*argv)[0] = (char *) "info"; return 1; } if (!strcmp(base, "losetup") || !strcmp(base, "dmlosetup")){ r = _process_losetup_switches(base, argc, argv, dev_dir); free(namebase); return r; } free(namebase); optarg = 0; optind = OPTIND_INIT; while ((ind = -1, c = GETOPTLONG_FN(*argc, *argv, "cCfG:j:m:M:no:O:ru:U:vy", long_options, NULL)) != -1) { if (c == ':' || c == '?') return 0; if (c == 'c' || c == 'C' || ind == COLS_ARG) _switches[COLS_ARG]++; if (c == 'f' || ind == FORCE_ARG) _switches[FORCE_ARG]++; if (c == 'r' || ind == READ_ONLY) _switches[READ_ONLY]++; if (c == 'j' || ind == MAJOR_ARG) { _switches[MAJOR_ARG]++; _int_args[MAJOR_ARG] = atoi(optarg); } if (c == 'm' || ind == MINOR_ARG) { _switches[MINOR_ARG]++; _int_args[MINOR_ARG] = atoi(optarg); } if (c == 'n' || ind == NOTABLE_ARG) _switches[NOTABLE_ARG]++; if (c == 'o' || ind == OPTIONS_ARG) { _switches[OPTIONS_ARG]++; _string_args[OPTIONS_ARG] = optarg; } if (ind == SEPARATOR_ARG) { _switches[SEPARATOR_ARG]++; _string_args[SEPARATOR_ARG] = optarg; } if (c == 'O' || ind == SORT_ARG) { _switches[SORT_ARG]++; _string_args[SORT_ARG] = optarg; } if (c == 'v' || ind == VERBOSE_ARG) _switches[VERBOSE_ARG]++; if (c == 'u' || ind == UUID_ARG) { _switches[UUID_ARG]++; _uuid = optarg; } if (c == 'y' || ind == YES_ARG) _switches[YES_ARG]++; if (ind == NOUDEVSYNC_ARG) _switches[NOUDEVSYNC_ARG]++; if (c == 'G' || ind == GID_ARG) { _switches[GID_ARG]++; _int_args[GID_ARG] = atoi(optarg); } if (c == 'U' || ind == UID_ARG) { _switches[UID_ARG]++; _int_args[UID_ARG] = atoi(optarg); } if (c == 'M' || ind == MODE_ARG) { _switches[MODE_ARG]++; /* FIXME Accept modes as per chmod */ _int_args[MODE_ARG] = (int) strtol(optarg, NULL, 8); } if ((ind == EXEC_ARG)) { _switches[EXEC_ARG]++; _command = optarg; } if ((ind == TARGET_ARG)) { _switches[TARGET_ARG]++; _target = optarg; } if ((ind == INACTIVE_ARG)) _switches[INACTIVE_ARG]++; if ((ind == NAMEPREFIXES_ARG)) _switches[NAMEPREFIXES_ARG]++; if ((ind == NOFLUSH_ARG)) _switches[NOFLUSH_ARG]++; if ((ind == NOHEADINGS_ARG)) _switches[NOHEADINGS_ARG]++; if ((ind == NOLOCKFS_ARG)) _switches[NOLOCKFS_ARG]++; if ((ind == NOOPENCOUNT_ARG)) _switches[NOOPENCOUNT_ARG]++; if ((ind == READAHEAD_ARG)) { _switches[READAHEAD_ARG]++; if (!strcasecmp(optarg, "auto")) _int_args[READAHEAD_ARG] = DM_READ_AHEAD_AUTO; else if (!strcasecmp(optarg, "none")) _int_args[READAHEAD_ARG] = DM_READ_AHEAD_NONE; else { for (s = optarg; isspace(*s); s++) ; if (*s == '+') _read_ahead_flags = DM_READ_AHEAD_MINIMUM_FLAG; _int_args[READAHEAD_ARG] = atoi(optarg); if (_int_args[READAHEAD_ARG] < -1) { log_error("Negative read ahead value " "(%d) is not understood.", _int_args[READAHEAD_ARG]); return 0; } } } if ((ind == ROWS_ARG)) _switches[ROWS_ARG]++; if ((ind == SHOWKEYS_ARG)) _switches[SHOWKEYS_ARG]++; if ((ind == TABLE_ARG)) { _switches[TABLE_ARG]++; _table = optarg; } if ((ind == TREE_ARG)) _switches[TREE_ARG]++; if ((ind == UNQUOTED_ARG)) _switches[UNQUOTED_ARG]++; if ((ind == VERSION_ARG)) _switches[VERSION_ARG]++; } if (_switches[VERBOSE_ARG] > 1) dm_log_init_verbose(_switches[VERBOSE_ARG] - 1); if ((_switches[MAJOR_ARG] && !_switches[MINOR_ARG]) || (!_switches[MAJOR_ARG] && _switches[MINOR_ARG])) { fprintf(stderr, "Please specify both major number and " "minor number.\n"); return 0; } if (_switches[TREE_ARG] && !_process_tree_options(_string_args[OPTIONS_ARG])) return 0; if (_switches[TABLE_ARG] && _switches[NOTABLE_ARG]) { fprintf(stderr, "--table and --notable are incompatible.\n"); return 0; } *argv += optind; *argc -= optind; return 1; } int main(int argc, char **argv) { struct command *c; int r = 1; const char *dev_dir; (void) setlocale(LC_ALL, ""); dev_dir = getenv ("DM_DEV_DIR"); if (dev_dir && *dev_dir) { if (!dm_set_dev_dir(dev_dir)) { fprintf(stderr, "Invalid DM_DEV_DIR environment variable value.\n"); goto out; } } else dev_dir = DEFAULT_DM_DEV_DIR; if (!_process_switches(&argc, &argv, dev_dir)) { fprintf(stderr, "Couldn't process command line.\n"); goto out; } if (_switches[VERSION_ARG]) { c = _find_command("version"); goto doit; } if (argc == 0) { _usage(stderr); goto out; } if (!(c = _find_command(argv[0]))) { fprintf(stderr, "Unknown command\n"); _usage(stderr); goto out; } if (argc < c->min_args + 1 || (c->max_args >= 0 && argc > c->max_args + 1)) { fprintf(stderr, "Incorrect number of arguments\n"); _usage(stderr); goto out; } if (!_switches[COLS_ARG] && !strcmp(c->name, "splitname")) _switches[COLS_ARG]++; if (_switches[COLS_ARG] && !_report_init(c)) goto out; if (_switches[NOUDEVSYNC_ARG]) dm_udev_set_sync_support(0); doit: if (!c->fn(argc, argv, NULL)) { fprintf(stderr, "Command failed\n"); goto out; } r = 0; out: if (_report) { dm_report_output(_report); dm_report_free(_report); } if (_dtree) dm_tree_free(_dtree); return r; }