/* * mdadm - manage Linux "md" devices aka RAID arrays. * * Copyright (C) 2001-2013 Neil Brown * * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * 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 * * Author: Neil Brown * Email: */ #include "mdadm.h" #include "udev.h" #include "md_u.h" #include "md_p.h" #include #include #include #include #include #ifndef FALLOC_FL_ZERO_RANGE #define FALLOC_FL_ZERO_RANGE 16 #endif static int round_size_and_verify(unsigned long long *size, int chunk) { if (*size == 0) return 0; *size &= ~(unsigned long long)(chunk - 1); if (*size == 0) { pr_err("Size cannot be smaller than chunk.\n"); return 1; } return 0; } /** * default_layout() - Get default layout for level. * @st: metadata requested, could be NULL. * @level: raid level requested. * @verbose: verbose level. * * Try to ask metadata handler first, otherwise use global defaults. * * Return: Layout or &UnSet, return value meaning depends of level used. */ int default_layout(struct supertype *st, int level, int verbose) { int layout = UnSet; mapping_t *layout_map = NULL; char *layout_name = NULL; if (st && st->ss->default_geometry) st->ss->default_geometry(st, &level, &layout, NULL); if (layout != UnSet) return layout; switch (level) { default: /* no layout */ layout = 0; break; case 0: layout = RAID0_ORIG_LAYOUT; break; case 10: layout = 0x102; /* near=2, far=1 */ layout_name = "n2"; break; case 5: case 6: layout_map = r5layout; break; case LEVEL_FAULTY: layout_map = faultylayout; break; } if (layout_map) { layout = map_name(layout_map, "default"); layout_name = map_num_s(layout_map, layout); } if (layout_name && verbose > 0) pr_err("layout defaults to %s\n", layout_name); return layout; } static pid_t write_zeroes_fork(int fd, struct shape *s, struct supertype *st, struct mddev_dev *dv) { const unsigned long long req_size = 1 << 30; unsigned long long offset_bytes, size_bytes, sz; sigset_t sigset; int ret = 0; pid_t pid; size_bytes = KIB_TO_BYTES(s->size); /* * If size_bytes is zero, this is a zoned raid array where * each disk is of a different size and uses its full * disk. Thus zero the entire disk. */ if (!size_bytes && !get_dev_size(fd, dv->devname, &size_bytes)) return -1; if (dv->data_offset != INVALID_SECTORS) offset_bytes = SEC_TO_BYTES(dv->data_offset); else offset_bytes = SEC_TO_BYTES(st->data_offset); pr_info("zeroing data from %lld to %lld on: %s\n", offset_bytes, size_bytes, dv->devname); pid = fork(); if (pid < 0) { pr_err("Could not fork to zero disks: %s\n", strerror(errno)); return pid; } else if (pid != 0) { return pid; } sigemptyset(&sigset); sigaddset(&sigset, SIGINT); sigprocmask(SIG_UNBLOCK, &sigset, NULL); while (size_bytes) { /* * Split requests to the kernel into 1GB chunks seeing the * fallocate() call is not interruptible and blocking a * ctrl-c for several minutes is not desirable. * * 1GB is chosen as a compromise: the user may still have * to wait several seconds if they ctrl-c on devices that * zero slowly, but will reduce the number of requests * required and thus the overhead on devices that perform * better. */ sz = size_bytes; if (sz >= req_size) sz = req_size; if (fallocate(fd, FALLOC_FL_ZERO_RANGE | FALLOC_FL_KEEP_SIZE, offset_bytes, sz)) { pr_err("zeroing %s failed: %s\n", dv->devname, strerror(errno)); ret = 1; break; } offset_bytes += sz; size_bytes -= sz; } exit(ret); } static int wait_for_zero_forks(int *zero_pids, int count) { int wstatus, ret = 0, i, sfd, wait_count = 0; struct signalfd_siginfo fdsi; bool interrupted = false; sigset_t sigset; ssize_t s; pid_t pid; for (i = 0; i < count; i++) if (zero_pids[i]) wait_count++; if (!wait_count) return 0; sigemptyset(&sigset); sigaddset(&sigset, SIGINT); sigaddset(&sigset, SIGCHLD); sigprocmask(SIG_BLOCK, &sigset, NULL); sfd = signalfd(-1, &sigset, 0); if (sfd < 0) { pr_err("Unable to create signalfd: %s\n", strerror(errno)); return 1; } while (wait_count) { s = read(sfd, &fdsi, sizeof(fdsi)); if (s != sizeof(fdsi)) { pr_err("Invalid signalfd read: %s\n", strerror(errno)); close(sfd); return 1; } if (fdsi.ssi_signo == SIGINT) { printf("\n"); pr_info("Interrupting zeroing processes, please wait...\n"); interrupted = true; } else if (fdsi.ssi_signo == SIGCHLD) { for (i = 0; i < count; i++) { if (!zero_pids[i]) continue; pid = waitpid(zero_pids[i], &wstatus, WNOHANG); if (pid <= 0) continue; zero_pids[i] = 0; if (!WIFEXITED(wstatus) || WEXITSTATUS(wstatus)) ret = 1; wait_count--; } } } close(sfd); if (interrupted) { pr_err("zeroing interrupted!\n"); return 1; } if (ret) pr_err("zeroing failed!\n"); else pr_info("zeroing finished\n"); return ret; } static int add_disk_to_super(int mdfd, struct shape *s, struct context *c, struct supertype *st, struct mddev_dev *dv, struct mdinfo *info, int have_container, int major_num, int *zero_pid) { dev_t rdev; int fd; if (dv->disposition == 'j') { info->disk.raid_disk = MD_DISK_ROLE_JOURNAL; info->disk.state = (1<disk.raid_disk < s->raiddisks) { info->disk.state = (1<disk.state = 0; } if (dv->writemostly == FlagSet) { if (major_num == BITMAP_MAJOR_CLUSTERED) { pr_err("Can not set %s --write-mostly with a clustered bitmap\n",dv->devname); return 1; } else { info->disk.state |= (1<failfast == FlagSet) info->disk.state |= (1<ss->external && st->container_devnm[0]) fd = open(dv->devname, O_RDWR); else fd = open(dv->devname, O_RDWR|O_EXCL); if (fd < 0) { pr_err("failed to open %s after earlier success - aborting\n", dv->devname); return 1; } if (!fstat_is_blkdev(fd, dv->devname, &rdev)) { close(fd); return 1; } info->disk.major = major(rdev); info->disk.minor = minor(rdev); } if (fd >= 0) remove_partitions(fd); if (st->ss->add_to_super(st, &info->disk, fd, dv->devname, dv->data_offset)) { ioctl(mdfd, STOP_ARRAY, NULL); close_fd(&fd); return 1; } st->ss->getinfo_super(st, info, NULL); if (fd >= 0 && s->write_zeroes) { *zero_pid = write_zeroes_fork(fd, s, st, dv); if (*zero_pid <= 0) { ioctl(mdfd, STOP_ARRAY, NULL); close(fd); return 1; } } if (have_container && c->verbose > 0) pr_err("Using %s for device %d\n", map_dev(info->disk.major, info->disk.minor, 0), info->disk.number); if (!have_container) { /* getinfo_super might have lost these ... */ info->disk.major = major(rdev); info->disk.minor = minor(rdev); } return 0; } static int update_metadata(int mdfd, struct shape *s, struct supertype *st, struct map_ent **map, struct mdinfo *info, char *chosen_name) { struct mdinfo info_new; struct map_ent *me = NULL; /* check to see if the uuid has changed due to these * metadata changes, and if so update the member array * and container uuid. Note ->write_init_super clears * the subarray cursor such that ->getinfo_super once * again returns container info. */ st->ss->getinfo_super(st, &info_new, NULL); if (st->ss->external && !is_container(s->level) && !same_uuid(info_new.uuid, info->uuid, 0)) { map_update(map, fd2devnm(mdfd), info_new.text_version, info_new.uuid, chosen_name); me = map_by_devnm(map, st->container_devnm); } if (st->ss->write_init_super(st)) { st->ss->free_super(st); return 1; } /* * Before activating the array, perform extra steps * required to configure the internal write-intent * bitmap. */ if (info_new.consistency_policy == CONSISTENCY_POLICY_BITMAP && st->ss->set_bitmap && st->ss->set_bitmap(st, info)) { st->ss->free_super(st); return 1; } /* update parent container uuid */ if (me) { char *path = xstrdup(me->path); st->ss->getinfo_super(st, &info_new, NULL); map_update(map, st->container_devnm, info_new.text_version, info_new.uuid, path); free(path); } flush_metadata_updates(st); st->ss->free_super(st); return 0; } static int add_disks(int mdfd, struct mdinfo *info, struct shape *s, struct context *c, struct supertype *st, struct map_ent **map, struct mddev_dev *devlist, int total_slots, int have_container, int insert_point, int major_num, char *chosen_name) { struct mddev_dev *moved_disk = NULL; int pass, raid_disk_num, dnum; int zero_pids[total_slots]; struct mddev_dev *dv; struct mdinfo *infos; sigset_t sigset, orig_sigset; int ret = 0; /* * Block SIGINT so the main thread will always wait for the * zeroing processes when being interrupted. Otherwise the * zeroing processes will finish their work in the background * keeping the disk busy. */ sigemptyset(&sigset); sigaddset(&sigset, SIGINT); sigaddset(&sigset, SIGCHLD); sigprocmask(SIG_BLOCK, &sigset, &orig_sigset); memset(zero_pids, 0, sizeof(zero_pids)); infos = xmalloc(sizeof(*infos) * total_slots); enable_fds(total_slots); for (pass = 1; pass <= 2; pass++) { for (dnum = 0, raid_disk_num = 0, dv = devlist; dv; dv = (dv->next) ? (dv->next) : moved_disk, dnum++) { if (dnum >= total_slots) abort(); if (dnum == insert_point) { raid_disk_num += 1; moved_disk = dv; continue; } if (strcasecmp(dv->devname, "missing") == 0) { raid_disk_num += 1; continue; } if (have_container) moved_disk = NULL; if (have_container && dnum < total_slots - 1) /* repeatedly use the container */ moved_disk = dv; switch(pass) { case 1: infos[dnum] = *info; infos[dnum].disk.number = dnum; infos[dnum].disk.raid_disk = raid_disk_num++; if (dv->disposition == 'j') raid_disk_num--; ret = add_disk_to_super(mdfd, s, c, st, dv, &infos[dnum], have_container, major_num, &zero_pids[dnum]); if (ret) goto out; break; case 2: infos[dnum].errors = 0; ret = add_disk(mdfd, st, info, &infos[dnum]); if (ret) { pr_err("ADD_NEW_DISK for %s failed: %s\n", dv->devname, strerror(errno)); if (errno == EINVAL && info->array.level == 0) { pr_err("Possibly your kernel doesn't support RAID0 layouts.\n"); pr_err("Either upgrade, or use --layout=dangerous\n"); } goto out; } break; } if (!have_container && dv == moved_disk && dnum != insert_point) break; } if (pass == 1) { ret = wait_for_zero_forks(zero_pids, total_slots); if (ret) goto out; ret = update_metadata(mdfd, s, st, map, info, chosen_name); if (ret) goto out; } } out: if (ret) wait_for_zero_forks(zero_pids, total_slots); free(infos); sigprocmask(SIG_SETMASK, &orig_sigset, NULL); return ret; } int Create(struct supertype *st, struct mddev_ident *ident, int subdevs, struct mddev_dev *devlist, struct shape *s, struct context *c) { /* * Create a new raid array. * * First check that necessary details are available * (i.e. level, raid-disks) * * Then check each disk to see what might be on it * and report anything interesting. * * If anything looks odd, and runstop not set, * abort. * * SET_ARRAY_INFO and ADD_NEW_DISK, and * if runstop==run, or raiddisks disks were used, * RUN_ARRAY */ int mdfd; unsigned long long minsize = 0, maxsize = 0; dev_policy_t *custom_pols = NULL; char *mindisc = NULL; char *maxdisc = NULL; char *name = ident->name; int *uuid = ident->uuid_set == 1 ? ident->uuid : NULL; int dnum; struct mddev_dev *dv; dev_t rdev; int fail = 0, warn = 0; int first_missing = subdevs * 2; int second_missing = subdevs * 2; int missing_disks = 0; int insert_point = subdevs * 2; /* where to insert a missing drive */ int total_slots; int rv; int bitmap_fd; int have_container = 0; int container_fd = -1; int need_mdmon = 0; unsigned long long bitmapsize; struct mdinfo info; int did_default = 0; int do_default_layout = 0; int do_default_chunk = 0; char chosen_name[1024]; struct map_ent *map = NULL; unsigned long long newsize; mdu_array_info_t inf; int major_num = BITMAP_MAJOR_HI; if (s->bitmap_file && strcmp(s->bitmap_file, "clustered") == 0) { major_num = BITMAP_MAJOR_CLUSTERED; if (c->nodes <= 1) { pr_err("At least 2 nodes are needed for cluster-md\n"); return 1; } } memset(&info, 0, sizeof(info)); if (s->level == UnSet && st && st->ss->default_geometry) st->ss->default_geometry(st, &s->level, NULL, NULL); if (s->level == UnSet) { pr_err("a RAID level is needed to create an array.\n"); return 1; } if (s->raiddisks < 4 && s->level == 6) { pr_err("at least 4 raid-devices needed for level 6\n"); return 1; } if (s->raiddisks > 256 && s->level == 6) { pr_err("no more than 256 raid-devices supported for level 6\n"); return 1; } if (s->raiddisks < 2 && s->level >= 4) { pr_err("at least 2 raid-devices needed for level %d\n", s->level); return 1; } if (s->level <= 0 && s->sparedisks) { pr_err("This level does not support spare devices\n"); return 1; } if (subdevs == 1 && strcmp(devlist->devname, "missing") != 0) { /* If given a single device, it might be a container, and we can * extract a device list from there */ int fd; memset(&inf, 0, sizeof(inf)); fd = open(devlist->devname, O_RDONLY); if (fd >= 0 && md_get_array_info(fd, &inf) == 0 && inf.raid_disks == 0) { /* yep, looks like a container */ if (st) { rv = st->ss->load_container(st, fd, devlist->devname); if (rv == 0) have_container = 1; } else { st = super_by_fd(fd, NULL); if (st && !(rv = st->ss-> load_container(st, fd, devlist->devname))) have_container = 1; else st = NULL; } if (have_container) { subdevs = s->raiddisks; first_missing = subdevs * 2; second_missing = subdevs * 2; insert_point = subdevs * 2; if (mddev_test_and_add_drive_policies(st, &custom_pols, fd, 1)) exit(1); } } if (fd >= 0) close(fd); } if (st && st->ss->external && s->sparedisks) { pr_err("This metadata type does not support spare disks at create time\n"); return 1; } if (subdevs > s->raiddisks+s->sparedisks+s->journaldisks) { pr_err("You have listed more devices (%d) than are in the array(%d)!\n", subdevs, s->raiddisks+s->sparedisks); return 1; } if (!have_container && subdevs < s->raiddisks+s->sparedisks+s->journaldisks) { pr_err("You haven't given enough devices (real or missing) to create this array\n"); return 1; } if (s->bitmap_file && s->level <= 0) { pr_err("bitmaps not meaningful with level %s\n", map_num(pers, s->level)?:"given"); return 1; } /* now set some defaults */ if (s->layout == UnSet) { do_default_layout = 1; s->layout = default_layout(st, s->level, c->verbose); } if (s->level == 10) /* check layout fits in array*/ if ((s->layout&255) * ((s->layout>>8)&255) > s->raiddisks) { pr_err("that layout requires at least %d devices\n", (s->layout&255) * ((s->layout>>8)&255)); return 1; } switch(s->level) { case 4: case 5: case 10: case 6: case 0: if (s->chunk == 0 || s->chunk == UnSet) { s->chunk = UnSet; do_default_chunk = 1; /* chunk will be set later */ } break; case LEVEL_LINEAR: /* a chunksize of zero 0s perfectly valid (and preferred) since 2.6.16 */ break; case 1: case LEVEL_FAULTY: case LEVEL_MULTIPATH: case LEVEL_CONTAINER: if (s->chunk) { pr_err("specifying chunk size is forbidden for this level\n"); return 1; } break; default: pr_err("unknown level %d\n", s->level); return 1; } if (s->size == MAX_SIZE) /* use '0' to mean 'max' now... */ s->size = 0; if (s->size && s->chunk && s->chunk != UnSet) if (round_size_and_verify(&s->size, s->chunk)) return 1; newsize = s->size * 2; if (st && ! st->ss->validate_geometry(st, s->level, s->layout, s->raiddisks, &s->chunk, s->size*2, s->data_offset, NULL, &newsize, s->consistency_policy, c->verbose >= 0)) return 1; if (s->chunk && s->chunk != UnSet) { newsize &= ~(unsigned long long)(s->chunk*2 - 1); if (do_default_chunk) { /* default chunk was just set */ if (c->verbose > 0) pr_err("chunk size defaults to %dK\n", s->chunk); if (round_size_and_verify(&s->size, s->chunk)) return 1; do_default_chunk = 0; } } if (s->size == 0) { s->size = newsize / 2; if (s->level == 1) /* If this is ever reshaped to RAID5, we will * need a chunksize. So round it off a bit * now just to be safe */ s->size &= ~(64ULL-1); if (s->size && c->verbose > 0) pr_err("setting size to %lluK\n", s->size); } /* now look at the subdevs */ info.array.active_disks = 0; info.array.working_disks = 0; dnum = 0; for (dv = devlist; dv; dv = dv->next) if (s->data_offset == VARIABLE_OFFSET) dv->data_offset = INVALID_SECTORS; else dv->data_offset = s->data_offset; for (dv=devlist; dv && !have_container; dv=dv->next, dnum++) { char *dname = dv->devname; unsigned long long freesize; int dfd; char *doff; if (strcasecmp(dname, "missing") == 0) { if (first_missing > dnum) first_missing = dnum; if (second_missing > dnum && dnum > first_missing) second_missing = dnum; missing_disks ++; continue; } if (s->data_offset == VARIABLE_OFFSET) { doff = strchr(dname, ':'); if (doff) { *doff++ = 0; dv->data_offset = parse_size(doff); } else dv->data_offset = INVALID_SECTORS; } else dv->data_offset = s->data_offset; dfd = open(dname, O_RDONLY); if (dfd < 0) { pr_err("cannot open %s: %s\n", dname, strerror(errno)); exit(2); } if (!fstat_is_blkdev(dfd, dname, NULL)) { close(dfd); exit(2); } info.array.working_disks++; if (dnum < s->raiddisks && dv->disposition != 'j') info.array.active_disks++; if (st == NULL) { struct createinfo *ci = conf_get_create_info(); if (ci) st = ci->supertype; } if (st == NULL) { /* Need to choose a default metadata, which is different * depending on geometry of array. */ int i; char *name = "default"; for(i = 0; !st && superlist[i]; i++) { st = superlist[i]->match_metadata_desc(name); if (!st) continue; if (do_default_layout) s->layout = default_layout(st, s->level, c->verbose); switch (st->ss->validate_geometry( st, s->level, s->layout, s->raiddisks, &s->chunk, s->size*2, dv->data_offset, dname, &freesize, s->consistency_policy, c->verbose > 0)) { case -1: /* Not valid, message printed, and not * worth checking any further */ exit(2); break; case 0: /* Geometry not valid */ free(st); st = NULL; s->chunk = do_default_chunk ? UnSet : s->chunk; break; case 1: /* All happy */ break; } } if (!st) { int dfd = open(dname, O_RDONLY|O_EXCL); if (dfd < 0) { pr_err("cannot open %s: %s\n", dname, strerror(errno)); exit(2); } pr_err("device %s not suitable for any style of array\n", dname); exit(2); } if (st->ss != &super0 || st->minor_version != 90) did_default = 1; } else { if (do_default_layout) s->layout = default_layout(st, s->level, 0); if (!st->ss->validate_geometry(st, s->level, s->layout, s->raiddisks, &s->chunk, s->size*2, dv->data_offset, dname, &freesize, s->consistency_policy, c->verbose >= 0)) { pr_err("%s is not suitable for this array.\n", dname); fail = 1; continue; } } if (drive_test_and_add_policies(st, &custom_pols, dfd, 1)) exit(1); close(dfd); if (dv->disposition == 'j') goto skip_size_check; /* skip write journal for size check */ freesize /= 2; /* convert to K */ if (s->chunk && s->chunk != UnSet) { /* round to chunk size */ freesize = freesize & ~(s->chunk-1); if (do_default_chunk) { /* default chunk was just set */ if (c->verbose > 0) pr_err("chunk size defaults to %dK\n", s->chunk); if (round_size_and_verify(&s->size, s->chunk)) return 1; do_default_chunk = 0; } } if (!freesize) { pr_err("no free space left on %s\n", dname); fail = 1; continue; } if (s->size && freesize < s->size) { pr_err("%s is smaller than given size. %lluK < %lluK + metadata\n", dname, freesize, s->size); fail = 1; continue; } if (maxdisc == NULL || (maxdisc && freesize > maxsize)) { maxdisc = dname; maxsize = freesize; } if (mindisc ==NULL || (mindisc && freesize < minsize)) { mindisc = dname; minsize = freesize; } skip_size_check: if (c->runstop != 1 || c->verbose >= 0) { int fd = open(dname, O_RDONLY); if (fd < 0) { pr_err("Cannot open %s: %s\n", dname, strerror(errno)); fail = 1; continue; } warn |= check_ext2(fd, dname); warn |= check_reiser(fd, dname); warn |= check_raid(fd, dname); if (strcmp(st->ss->name, "1.x") == 0 && st->minor_version >= 1) /* metadata at front */ warn |= check_partitions(fd, dname, 0, 0); else if (s->level == 1 || is_container(s->level) || (s->level == 0 && s->raiddisks == 1)) /* partitions could be meaningful */ warn |= check_partitions(fd, dname, freesize*2, s->size*2); else /* partitions cannot be meaningful */ warn |= check_partitions(fd, dname, 0, 0); if (strcmp(st->ss->name, "1.x") == 0 && st->minor_version >= 1 && did_default && s->level == 1 && (warn & 1024) == 0) { warn |= 1024; pr_err("Note: this array has metadata at the start and\n" " may not be suitable as a boot device. If you plan to\n" " store '/boot' on this device please ensure that\n" " your boot-loader understands md/v1.x metadata, or use\n" " --metadata=0.90\n"); } close(fd); } } if (missing_disks == dnum && !have_container) { pr_err("Subdevs can't be all missing\n"); return 1; } if (s->raiddisks + s->sparedisks > st->max_devs) { pr_err("Too many devices: %s metadata only supports %d\n", st->ss->name, st->max_devs); return 1; } if (have_container) info.array.working_disks = s->raiddisks; if (fail) { pr_err("create aborted\n"); return 1; } if (s->size == 0) { if (mindisc == NULL && !have_container) { pr_err("no size and no drives given - aborting create.\n"); return 1; } if (s->level > 0 || s->level == LEVEL_MULTIPATH || s->level == LEVEL_FAULTY || st->ss->external) { /* size is meaningful */ if (!st->ss->validate_geometry(st, s->level, s->layout, s->raiddisks, &s->chunk, minsize*2, s->data_offset, NULL, NULL, s->consistency_policy, 0)) { pr_err("devices too large for RAID level %d\n", s->level); return 1; } s->size = minsize; if (s->level == 1) /* If this is ever reshaped to RAID5, we will * need a chunksize. So round it off a bit * now just to be safe */ s->size &= ~(64ULL-1); if (c->verbose > 0) pr_err("size set to %lluK\n", s->size); } } if (!s->bitmap_file && !st->ss->external && s->level >= 1 && st->ss->add_internal_bitmap && s->journaldisks == 0 && (s->consistency_policy != CONSISTENCY_POLICY_RESYNC && s->consistency_policy != CONSISTENCY_POLICY_PPL) && (s->write_behind || s->size > 100*1024*1024ULL)) { if (c->verbose > 0) pr_err("automatically enabling write-intent bitmap on large array\n"); s->bitmap_file = "internal"; } if (s->bitmap_file && str_is_none(s->bitmap_file) == true) s->bitmap_file = NULL; if (s->consistency_policy == CONSISTENCY_POLICY_PPL && !st->ss->write_init_ppl) { pr_err("%s metadata does not support PPL\n", st->ss->name); return 1; } if (st->ss == &super_imsm && s->level == 10 && s->raiddisks > 4) { /* Print no matter runstop was specifed */ pr_err("Warning! VROC UEFI driver does not support RAID10 in requested layout.\n"); pr_err("Array won't be suitable as boot device.\n"); warn = 1; } if (!have_container && s->level > 0 && ((maxsize-s->size)*100 > maxsize)) { if (c->runstop != 1 || c->verbose >= 0) pr_err("largest drive (%s) exceeds size (%lluK) by more than 1%%\n", maxdisc, s->size); warn = 1; } if (st->ss->detail_platform && st->ss->detail_platform(0, 1, NULL) != 0) { if (c->runstop != 1 || c->verbose >= 0) pr_err("%s unable to enumerate platform support\n" " array may not be compatible with hardware/firmware\n", st->ss->name); warn = 1; } st->nodes = c->nodes; st->cluster_name = c->homecluster; if (warn) { if (c->runstop!= 1) { if (!ask("Continue creating array")) { pr_err("create aborted.\n"); return 1; } } else { if (c->verbose > 0) pr_err("creation continuing despite oddities due to --run\n"); } } /* If this is raid4/5, we want to configure the last active slot * as missing, so that a reconstruct happens (faster than re-parity) * FIX: Can we do this for raid6 as well? */ if (st->ss->external == 0 && s->assume_clean == 0 && c->force == 0 && first_missing >= s->raiddisks) { switch (s->level) { case 4: case 5: insert_point = s->raiddisks-1; s->sparedisks++; info.array.active_disks--; missing_disks++; break; default: break; } } /* For raid6, if creating with 1 missing drive, make a good drive * into a spare, else the create will fail */ if (s->assume_clean == 0 && c->force == 0 && first_missing < s->raiddisks && st->ss->external == 0 && second_missing >= s->raiddisks && s->level == 6) { insert_point = s->raiddisks - 1; if (insert_point == first_missing) insert_point--; s->sparedisks ++; info.array.active_disks--; missing_disks++; } if (s->level <= 0 && first_missing < subdevs * 2) { pr_err("This level does not support missing devices\n"); return 1; } /* We need to create the device */ map_lock(&map); mdfd = create_mddev(ident->devname, ident->name, c->autof, LOCAL, chosen_name, 1); if (mdfd < 0) { map_unlock(&map); return 1; } /* verify if chosen_name is not in use, * it could be in conflict with already existing device * e.g. container, array */ if (strncmp(chosen_name, DEV_MD_DIR, DEV_MD_DIR_LEN) == 0 && map_by_name(&map, chosen_name + DEV_MD_DIR_LEN)) { pr_err("Array name %s is in use already.\n", chosen_name); close(mdfd); map_unlock(&map); udev_unblock(); return 1; } memset(&inf, 0, sizeof(inf)); md_get_array_info(mdfd, &inf); if (inf.working_disks != 0) { pr_err("another array by this name is already running.\n"); goto abort_locked; } /* Ok, lets try some ioctls */ info.array.level = s->level; info.array.size = s->size; info.array.raid_disks = s->raiddisks; /* The kernel should *know* what md_minor we are dealing * with, but it chooses to trust me instead. Sigh */ info.array.md_minor = 0; if (fstat_is_blkdev(mdfd, chosen_name, &rdev)) info.array.md_minor = minor(rdev); info.array.not_persistent = 0; if (((s->level == 4 || s->level == 5) && (insert_point < s->raiddisks || first_missing < s->raiddisks)) || (s->level == 6 && (insert_point < s->raiddisks || second_missing < s->raiddisks)) || (s->level <= 0) || s->assume_clean) { info.array.state = 1; /* clean, but one+ drive will be missing*/ info.resync_start = MaxSector; } else { info.array.state = 0; /* not clean, but no errors */ info.resync_start = 0; } if (s->level == 10) { /* for raid10, the bitmap size is the capacity of the array, * which is array.size * raid_disks / ncopies; * .. but convert to sectors. */ int ncopies = ((s->layout>>8) & 255) * (s->layout & 255); bitmapsize = s->size * s->raiddisks / ncopies * 2; /* printf("bms=%llu as=%d rd=%d nc=%d\n", bitmapsize, s->size, s->raiddisks, ncopies);*/ } else bitmapsize = s->size * 2; /* There is lots of redundancy in these disk counts, * raid_disks is the most meaningful value * it describes the geometry of the array * it is constant * nr_disks is total number of used slots. * it should be raid_disks+spare_disks * spare_disks is the number of extra disks present * see above * active_disks is the number of working disks in * active slots. (With raid_disks) * working_disks is the total number of working disks, * including spares * failed_disks is the number of disks marked failed * * Ideally, the kernel would keep these (except raid_disks) * up-to-date as we ADD_NEW_DISK, but it doesn't (yet). * So for now, we assume that all raid and spare * devices will be given. */ info.array.spare_disks=s->sparedisks; info.array.failed_disks=missing_disks; info.array.nr_disks = info.array.working_disks + info.array.failed_disks; info.array.layout = s->layout; info.array.chunk_size = s->chunk*1024; if (*name == 0) { /* base name on devname */ /* /dev/md0 -> 0 * /dev/md_d0 -> d0 * /dev/md_foo -> foo * /dev/md/1 -> 1 * /dev/md/d1 -> d1 * /dev/md/home -> home * /dev/mdhome -> home */ /* FIXME compare this with rules in create_mddev */ name = strrchr(chosen_name, '/'); if (name) { name++; if (strncmp(name, "md_", 3) == 0 && strlen(name) > 3 && (name - chosen_name) == 5 /* /dev/ */) name += 3; else if (strncmp(name, "md", 2) == 0 && strlen(name) > 2 && isdigit(name[2]) && (name - chosen_name) == 5 /* /dev/ */) name += 2; } } if (!st->ss->init_super(st, &info.array, s, name, c->homehost, uuid, s->data_offset)) goto abort_locked; total_slots = info.array.nr_disks; st->ss->getinfo_super(st, &info, NULL); if (sysfs_init(&info, mdfd, NULL)) { pr_err("unable to initialize sysfs\n"); goto abort_locked; } if (did_default) { if (is_subarray(info.text_version)) { char devnm[MD_NAME_MAX]; struct mdinfo *mdi; sysfs_get_container_devnm(&info, devnm); mdi = sysfs_read(-1, devnm, GET_VERSION | GET_DEVS); if (!mdi) { pr_err("Cannot open sysfs for container %s\n", devnm); goto abort_locked; } if (sysfs_test_and_add_drive_policies(st, &custom_pols, mdi, 1)) goto abort_locked; if (c->verbose >= 0) pr_info("Creating array inside %s container /dev/%s\n", mdi->text_version, devnm); sysfs_free(mdi); } else if (c->verbose >= 0) { pr_info("Defaulting to version %s metadata\n", info.text_version); } } map_update(&map, fd2devnm(mdfd), info.text_version, info.uuid, chosen_name); /* Keep map locked until devices have been added to array * to stop another mdadm from finding and using those devices. */ if (s->bitmap_file && (strcmp(s->bitmap_file, "internal") == 0 || strcmp(s->bitmap_file, "clustered") == 0)) { if (!st->ss->add_internal_bitmap) { pr_err("internal bitmaps not supported with %s metadata\n", st->ss->name); goto abort_locked; } if (st->ss->add_internal_bitmap(st, &s->bitmap_chunk, c->delay, s->write_behind, bitmapsize, 1, major_num)) { pr_err("Given bitmap chunk size not supported.\n"); goto abort_locked; } s->bitmap_file = NULL; } if (sysfs_init(&info, mdfd, NULL)) { pr_err("unable to initialize sysfs\n"); goto abort_locked; } if (st->ss->external && st->container_devnm[0]) { /* member */ /* When creating a member, we need to be careful * to negotiate with mdmon properly. * If it is already running, we cannot write to * the devices and must ask it to do that part. * If it isn't running, we write to the devices, * and then start it. * We hold an exclusive open on the container * device to make sure mdmon doesn't exit after * we checked that it is running. * * For now, fail if it is already running. */ container_fd = open_dev_excl(st->container_devnm); if (container_fd < 0) { pr_err("Cannot get exclusive open on container - weird.\n"); goto abort_locked; } if (mdmon_running(st->container_devnm)) { if (c->verbose) pr_err("reusing mdmon for %s.\n", st->container_devnm); st->update_tail = &st->updates; } else need_mdmon = 1; } rv = set_array_info(mdfd, st, &info); if (rv) { pr_err("failed to set array info for %s: %s\n", chosen_name, strerror(errno)); goto abort_locked; } if (s->bitmap_file) { int uuid[4]; st->ss->uuid_from_super(st, uuid); if (CreateBitmap(s->bitmap_file, c->force, (char*)uuid, s->bitmap_chunk, c->delay, s->write_behind, bitmapsize, major_num)) { goto abort_locked; } bitmap_fd = open(s->bitmap_file, O_RDWR); if (bitmap_fd < 0) { pr_err("weird: %s cannot be opened\n", s->bitmap_file); goto abort_locked; } if (ioctl(mdfd, SET_BITMAP_FILE, bitmap_fd) < 0) { pr_err("Cannot set bitmap file for %s: %s\n", chosen_name, strerror(errno)); goto abort_locked; } } if (add_disks(mdfd, &info, s, c, st, &map, devlist, total_slots, have_container, insert_point, major_num, chosen_name)) goto abort_locked; map_unlock(&map); if (is_container(s->level)) { /* No need to start. But we should signal udev to * create links */ sysfs_uevent(&info, "change"); if (c->verbose >= 0) pr_err("container %s prepared.\n", chosen_name); wait_for(chosen_name, mdfd); } else if (c->runstop == 1 || subdevs >= s->raiddisks) { if (st->ss->external) { int err; switch(s->level) { case LEVEL_LINEAR: case LEVEL_MULTIPATH: case 0: err = sysfs_set_str(&info, NULL, "array_state", c->readonly ? "readonly" : "active"); need_mdmon = 0; break; default: err = sysfs_set_str(&info, NULL, "array_state", "readonly"); break; } sysfs_set_safemode(&info, info.safe_mode_delay); if (err) { pr_err("failed to activate array.\n"); ioctl(mdfd, STOP_ARRAY, NULL); goto abort; } } else if (c->readonly && sysfs_attribute_available( &info, NULL, "array_state")) { if (sysfs_set_str(&info, NULL, "array_state", "readonly") < 0) { pr_err("Failed to start array: %s\n", strerror(errno)); ioctl(mdfd, STOP_ARRAY, NULL); goto abort; } } else { /* param is not actually used */ mdu_param_t param; if (ioctl(mdfd, RUN_ARRAY, ¶m)) { pr_err("RUN_ARRAY failed: %s\n", strerror(errno)); if (errno == 524 /* ENOTSUP */ && info.array.level == 0) cont_err("Please use --layout=original or --layout=alternate\n"); if (info.array.chunk_size & (info.array.chunk_size-1)) { cont_err("Problem may be that chunk size is not a power of 2\n"); } ioctl(mdfd, STOP_ARRAY, NULL); goto abort; } /* if start_ro module parameter is set, array is * auto-read-only, which is bad as the resync won't * start. So lets make it read-write now. */ ioctl(mdfd, RESTART_ARRAY_RW, NULL); } if (c->verbose >= 0) pr_info("array %s started.\n", chosen_name); if (st->ss->external && st->container_devnm[0]) { if (need_mdmon) { start_mdmon(st->container_devnm); if (wait_for_mdmon_control_socket(st->container_devnm) != MDADM_STATUS_SUCCESS) goto abort; } ping_monitor(st->container_devnm); close(container_fd); } wait_for(chosen_name, mdfd); } else { pr_err("not starting array - not enough devices.\n"); } udev_unblock(); close(mdfd); sysfs_uevent(&info, "change"); dev_policy_free(custom_pols); return 0; abort: udev_unblock(); map_lock(&map); abort_locked: map_remove(&map, fd2devnm(mdfd)); map_unlock(&map); close_fd(&mdfd); close_fd(&container_fd); dev_policy_free(custom_pols); return 1; }