/* * 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 "dlink.h" #include #include #include #include #if ! defined(__BIG_ENDIAN) && ! defined(__LITTLE_ENDIAN) #error no endian defined #endif #include "md_u.h" #include "md_p.h" int restore_backup(struct supertype *st, struct mdinfo *content, int working_disks, int next_spare, char **backup_filep, int verbose) { int i; int *fdlist; struct mdinfo *dev; int err; int disk_count = next_spare + working_disks; char *backup_file = *backup_filep; dprintf("Called restore_backup()\n"); fdlist = xmalloc(sizeof(int) * disk_count); enable_fds(next_spare); for (i = 0; i < next_spare; i++) fdlist[i] = -1; for (dev = content->devs; dev; dev = dev->next) { char buf[22]; int fd; sprintf(buf, "%d:%d", dev->disk.major, dev->disk.minor); fd = dev_open(buf, O_RDWR); if (dev->disk.raid_disk >= 0) fdlist[dev->disk.raid_disk] = fd; else fdlist[next_spare++] = fd; } if (!backup_file) { backup_file = locate_backup(content->sys_name); *backup_filep = backup_file; } if (st->ss->external && st->ss->recover_backup) err = st->ss->recover_backup(st, content); else err = Grow_restart(st, content, fdlist, next_spare, backup_file, verbose > 0); while (next_spare > 0) { next_spare--; if (fdlist[next_spare] >= 0) close(fdlist[next_spare]); } free(fdlist); if (err) { pr_err("Failed to restore critical section for reshape - sorry.\n"); if (!backup_file) pr_err("Possibly you need to specify a --backup-file\n"); return 1; } dprintf("restore_backup() returns status OK.\n"); return 0; } int Grow_Add_device(char *devname, int fd, char *newdev) { /* Add a device to an active array. * Currently, just extend a linear array. * This requires writing a new superblock on the * new device, calling the kernel to add the device, * and if that succeeds, update the superblock on * all other devices. * This means that we need to *find* all other devices. */ struct mdinfo info; dev_t rdev; int nfd, fd2; int d, nd; struct supertype *st = NULL; char *subarray = NULL; if (md_get_array_info(fd, &info.array) < 0) { pr_err("cannot get array info for %s\n", devname); return 1; } if (info.array.level != -1) { pr_err("can only add devices to linear arrays\n"); return 1; } st = super_by_fd(fd, &subarray); if (!st) { pr_err("cannot handle arrays with superblock version %d\n", info.array.major_version); return 1; } if (subarray) { pr_err("Cannot grow linear sub-arrays yet\n"); free(subarray); free(st); return 1; } nfd = open(newdev, O_RDWR|O_EXCL|O_DIRECT); if (nfd < 0) { pr_err("cannot open %s\n", newdev); free(st); return 1; } if (!fstat_is_blkdev(nfd, newdev, &rdev)) { close(nfd); free(st); return 1; } /* now check out all the devices and make sure we can read the * superblock */ for (d=0 ; d < info.array.raid_disks ; d++) { mdu_disk_info_t disk; char *dv; st->ss->free_super(st); disk.number = d; if (md_get_disk_info(fd, &disk) < 0) { pr_err("cannot get device detail for device %d\n", d); close(nfd); free(st); return 1; } dv = map_dev(disk.major, disk.minor, 1); if (!dv) { pr_err("cannot find device file for device %d\n", d); close(nfd); free(st); return 1; } fd2 = dev_open(dv, O_RDWR); if (fd2 < 0) { pr_err("cannot open device file %s\n", dv); close(nfd); free(st); return 1; } if (st->ss->load_super(st, fd2, NULL)) { pr_err("cannot find super block on %s\n", dv); close(nfd); close(fd2); free(st); return 1; } close(fd2); } /* Ok, looks good. Lets update the superblock and write it out to * newdev. */ info.disk.number = d; info.disk.major = major(rdev); info.disk.minor = minor(rdev); info.disk.raid_disk = d; info.disk.state = (1 << MD_DISK_SYNC) | (1 << MD_DISK_ACTIVE); if (st->ss->update_super(st, &info, UOPT_SPEC_LINEAR_GROW_NEW, newdev, 0, 0, NULL) != 0) { pr_err("Preparing new metadata failed on %s\n", newdev); close(nfd); return 1; } if (st->ss->store_super(st, nfd)) { pr_err("Cannot store new superblock on %s\n", newdev); close(nfd); return 1; } close(nfd); if (ioctl(fd, ADD_NEW_DISK, &info.disk) != 0) { pr_err("Cannot add new disk to this array\n"); return 1; } /* Well, that seems to have worked. * Now go through and update all superblocks */ if (md_get_array_info(fd, &info.array) < 0) { pr_err("cannot get array info for %s\n", devname); return 1; } nd = d; for (d=0 ; d < info.array.raid_disks ; d++) { mdu_disk_info_t disk; char *dv; disk.number = d; if (md_get_disk_info(fd, &disk) < 0) { pr_err("cannot get device detail for device %d\n", d); return 1; } dv = map_dev(disk.major, disk.minor, 1); if (!dv) { pr_err("cannot find device file for device %d\n", d); return 1; } fd2 = dev_open(dv, O_RDWR); if (fd2 < 0) { pr_err("cannot open device file %s\n", dv); return 1; } if (st->ss->load_super(st, fd2, NULL)) { pr_err("cannot find super block on %s\n", dv); close(fd); close(fd2); return 1; } info.array.raid_disks = nd+1; info.array.nr_disks = nd+1; info.array.active_disks = nd+1; info.array.working_disks = nd+1; if (st->ss->update_super(st, &info, UOPT_SPEC_LINEAR_GROW_UPDATE, dv, 0, 0, NULL) != 0) { pr_err("Updating metadata failed on %s\n", dv); close(fd2); return 1; } if (st->ss->store_super(st, fd2)) { pr_err("Cannot store new superblock on %s\n", dv); close(fd2); return 1; } close(fd2); } return 0; } int Grow_addbitmap(char *devname, int fd, struct context *c, struct shape *s) { /* * First check that array doesn't have a bitmap * Then create the bitmap * Then add it * * For internal bitmaps, we need to check the version, * find all the active devices, and write the bitmap block * to all devices */ mdu_bitmap_file_t bmf; mdu_array_info_t array; struct supertype *st; char *subarray = NULL; int major = BITMAP_MAJOR_HI; unsigned long long bitmapsize, array_size; struct mdinfo *mdi; /* * We only ever get called if s->bitmap_file is != NULL, so this check * is just here to quiet down static code checkers. */ if (!s->bitmap_file) return 1; if (strcmp(s->bitmap_file, "clustered") == 0) major = BITMAP_MAJOR_CLUSTERED; if (ioctl(fd, GET_BITMAP_FILE, &bmf) != 0) { if (errno == ENOMEM) pr_err("Memory allocation failure.\n"); else pr_err("bitmaps not supported by this kernel.\n"); return 1; } if (bmf.pathname[0]) { if (str_is_none(s->bitmap_file) == true) { if (ioctl(fd, SET_BITMAP_FILE, -1) != 0) { pr_err("failed to remove bitmap %s\n", bmf.pathname); return 1; } return 0; } pr_err("%s already has a bitmap (%s)\n", devname, bmf.pathname); return 1; } if (md_get_array_info(fd, &array) != 0) { pr_err("cannot get array status for %s\n", devname); return 1; } if (array.state & (1 << MD_SB_BITMAP_PRESENT)) { if (str_is_none(s->bitmap_file) == true) { array.state &= ~(1 << MD_SB_BITMAP_PRESENT); if (md_set_array_info(fd, &array) != 0) { if (array.state & (1 << MD_SB_CLUSTERED)) pr_err("failed to remove clustered bitmap.\n"); else pr_err("failed to remove internal bitmap.\n"); return 1; } return 0; } pr_err("bitmap already present on %s\n", devname); return 1; } if (str_is_none(s->bitmap_file) == true) { pr_err("no bitmap found on %s\n", devname); return 1; } if (array.level <= 0) { pr_err("Bitmaps not meaningful with level %s\n", map_num(pers, array.level)?:"of this array"); return 1; } bitmapsize = array.size; bitmapsize <<= 1; if (get_dev_size(fd, NULL, &array_size) && array_size > (0x7fffffffULL << 9)) { /* Array is big enough that we cannot trust array.size * try other approaches */ bitmapsize = get_component_size(fd); } if (bitmapsize == 0) { pr_err("Cannot reliably determine size of array to create bitmap - sorry.\n"); return 1; } if (array.level == 10) { int ncopies; ncopies = (array.layout & 255) * ((array.layout >> 8) & 255); bitmapsize = bitmapsize * array.raid_disks / ncopies; if (strcmp(s->bitmap_file, "clustered") == 0 && !is_near_layout_10(array.layout)) { pr_err("only near layout is supported with clustered raid10\n"); return 1; } } st = super_by_fd(fd, &subarray); if (!st) { pr_err("Cannot understand version %d.%d\n", array.major_version, array.minor_version); return 1; } if (subarray) { pr_err("Cannot add bitmaps to sub-arrays yet\n"); free(subarray); free(st); return 1; } mdi = sysfs_read(fd, NULL, GET_CONSISTENCY_POLICY); if (mdi) { if (mdi->consistency_policy == CONSISTENCY_POLICY_PPL) { pr_err("Cannot add bitmap to array with PPL\n"); free(mdi); free(st); return 1; } free(mdi); } if (strcmp(s->bitmap_file, "internal") == 0 || strcmp(s->bitmap_file, "clustered") == 0) { int rv; int d; int offset_setable = 0; if (st->ss->add_internal_bitmap == NULL) { pr_err("Internal bitmaps not supported with %s metadata\n", st->ss->name); return 1; } st->nodes = c->nodes; st->cluster_name = c->homecluster; mdi = sysfs_read(fd, NULL, GET_BITMAP_LOCATION); if (mdi) offset_setable = 1; for (d = 0; d < st->max_devs; d++) { mdu_disk_info_t disk; char *dv; int fd2; disk.number = d; if (md_get_disk_info(fd, &disk) < 0) continue; if (disk.major == 0 && disk.minor == 0) continue; if ((disk.state & (1 << MD_DISK_SYNC)) == 0) continue; dv = map_dev(disk.major, disk.minor, 1); if (!dv) continue; if ((disk.state & (1 << MD_DISK_WRITEMOSTLY)) && (strcmp(s->bitmap_file, "clustered") == 0)) { pr_err("%s disks marked write-mostly are not supported with clustered bitmap\n",devname); free(mdi); return 1; } fd2 = dev_open(dv, O_RDWR); if (fd2 < 0) continue; rv = st->ss->load_super(st, fd2, NULL); if (!rv) { rv = st->ss->add_internal_bitmap( st, &s->bitmap_chunk, c->delay, s->write_behind, bitmapsize, offset_setable, major); if (!rv) { st->ss->write_bitmap(st, fd2, NodeNumUpdate); } else { pr_err("failed to create internal bitmap - chunksize problem.\n"); } } else { pr_err("failed to load super-block.\n"); } close(fd2); if (rv) { free(mdi); return 1; } } if (offset_setable) { st->ss->getinfo_super(st, mdi, NULL); if (sysfs_init(mdi, fd, NULL)) { pr_err("failed to initialize sysfs.\n"); free(mdi); } rv = sysfs_set_num_signed(mdi, NULL, "bitmap/location", mdi->bitmap_offset); free(mdi); } else { if (strcmp(s->bitmap_file, "clustered") == 0) array.state |= (1 << MD_SB_CLUSTERED); array.state |= (1 << MD_SB_BITMAP_PRESENT); rv = md_set_array_info(fd, &array); } if (rv < 0) { if (errno == EBUSY) pr_err("Cannot add bitmap while array is resyncing or reshaping etc.\n"); pr_err("failed to set internal bitmap.\n"); return 1; } } else { int uuid[4]; int bitmap_fd; int d; int max_devs = st->max_devs; /* try to load a superblock */ for (d = 0; d < max_devs; d++) { mdu_disk_info_t disk; char *dv; int fd2; disk.number = d; if (md_get_disk_info(fd, &disk) < 0) continue; if ((disk.major==0 && disk.minor == 0) || (disk.state & (1 << MD_DISK_REMOVED))) continue; dv = map_dev(disk.major, disk.minor, 1); if (!dv) continue; fd2 = dev_open(dv, O_RDONLY); if (fd2 >= 0) { if (st->ss->load_super(st, fd2, NULL) == 0) { close(fd2); st->ss->uuid_from_super(st, uuid); break; } close(fd2); } } if (d == max_devs) { pr_err("cannot find UUID for array!\n"); return 1; } if (CreateBitmap(s->bitmap_file, c->force, (char*)uuid, s->bitmap_chunk, c->delay, s->write_behind, bitmapsize, major)) { return 1; } bitmap_fd = open(s->bitmap_file, O_RDWR); if (bitmap_fd < 0) { pr_err("weird: %s cannot be opened\n", s->bitmap_file); return 1; } if (ioctl(fd, SET_BITMAP_FILE, bitmap_fd) < 0) { int err = errno; if (errno == EBUSY) pr_err("Cannot add bitmap while array is resyncing or reshaping etc.\n"); pr_err("Cannot set bitmap file for %s: %s\n", devname, strerror(err)); close_fd(&bitmap_fd); return 1; } close_fd(&bitmap_fd); } return 0; } int Grow_consistency_policy(char *devname, int fd, struct context *c, struct shape *s) { struct supertype *st; struct mdinfo *sra; struct mdinfo *sd; char *subarray = NULL; int ret = 0; char container_dev[PATH_MAX]; char buf[SYSFS_MAX_BUF_SIZE]; if (s->consistency_policy != CONSISTENCY_POLICY_RESYNC && s->consistency_policy != CONSISTENCY_POLICY_PPL) { pr_err("Operation not supported for consistency policy %s\n", map_num_s(consistency_policies, s->consistency_policy)); return 1; } st = super_by_fd(fd, &subarray); if (!st) return 1; sra = sysfs_read(fd, NULL, GET_CONSISTENCY_POLICY|GET_LEVEL| GET_DEVS|GET_STATE); if (!sra) { ret = 1; goto free_st; } if (s->consistency_policy == CONSISTENCY_POLICY_PPL && !st->ss->write_init_ppl) { pr_err("%s metadata does not support PPL\n", st->ss->name); ret = 1; goto free_info; } if (sra->array.level != 5) { pr_err("Operation not supported for array level %d\n", sra->array.level); ret = 1; goto free_info; } if (sra->consistency_policy == (unsigned)s->consistency_policy) { pr_err("Consistency policy is already %s\n", map_num_s(consistency_policies, s->consistency_policy)); ret = 1; goto free_info; } else if (sra->consistency_policy != CONSISTENCY_POLICY_RESYNC && sra->consistency_policy != CONSISTENCY_POLICY_PPL) { pr_err("Current consistency policy is %s, cannot change to %s\n", map_num_s(consistency_policies, sra->consistency_policy), map_num_s(consistency_policies, s->consistency_policy)); ret = 1; goto free_info; } if (s->consistency_policy == CONSISTENCY_POLICY_PPL) { if (sysfs_get_str(sra, NULL, "sync_action", buf, sizeof(buf)) <= 0) { ret = 1; goto free_info; } else if (strcmp(buf, "reshape\n") == 0) { pr_err("PPL cannot be enabled when reshape is in progress\n"); ret = 1; goto free_info; } } if (subarray) { enum update_opt update; if (s->consistency_policy == CONSISTENCY_POLICY_PPL) update = UOPT_PPL; else update = UOPT_NO_PPL; sprintf(container_dev, "/dev/%s", st->container_devnm); ret = Update_subarray(container_dev, subarray, update, NULL, c->verbose); if (ret) goto free_info; } if (s->consistency_policy == CONSISTENCY_POLICY_PPL) { struct mdinfo info; if (subarray) { struct mdinfo *mdi; int cfd; cfd = open(container_dev, O_RDWR|O_EXCL); if (cfd < 0) { pr_err("Failed to open %s\n", container_dev); ret = 1; goto free_info; } ret = st->ss->load_container(st, cfd, st->container_devnm); close(cfd); if (ret) { pr_err("Cannot read superblock for %s\n", container_dev); goto free_info; } mdi = st->ss->container_content(st, subarray); info = *mdi; free(mdi); } for (sd = sra->devs; sd; sd = sd->next) { int dfd; char *devpath; devpath = map_dev(sd->disk.major, sd->disk.minor, 0); dfd = dev_open(devpath, O_RDWR); if (dfd < 0) { pr_err("Failed to open %s\n", devpath); ret = 1; goto free_info; } if (!subarray) { ret = st->ss->load_super(st, dfd, NULL); if (ret) { pr_err("Failed to load super-block.\n"); close(dfd); goto free_info; } ret = st->ss->update_super(st, sra, UOPT_PPL, devname, c->verbose, 0, NULL); if (ret) { close(dfd); st->ss->free_super(st); goto free_info; } st->ss->getinfo_super(st, &info, NULL); } ret |= sysfs_set_num(sra, sd, "ppl_sector", info.ppl_sector); ret |= sysfs_set_num(sra, sd, "ppl_size", info.ppl_size); if (ret) { pr_err("Failed to set PPL attributes for %s\n", sd->sys_name); close(dfd); st->ss->free_super(st); goto free_info; } ret = st->ss->write_init_ppl(st, &info, dfd); if (ret) pr_err("Failed to write PPL\n"); close(dfd); if (!subarray) st->ss->free_super(st); if (ret) goto free_info; } } ret = sysfs_set_str(sra, NULL, "consistency_policy", map_num_s(consistency_policies, s->consistency_policy)); if (ret) pr_err("Failed to change array consistency policy\n"); free_info: sysfs_free(sra); free_st: free(st); free(subarray); return ret; } /* * When reshaping an array we might need to backup some data. * This is written to all spares with a 'super_block' describing it. * The superblock goes 4K from the end of the used space on the * device. * It if written after the backup is complete. * It has the following structure. */ static struct mdp_backup_super { char magic[16]; /* md_backup_data-1 or -2 */ __u8 set_uuid[16]; __u64 mtime; /* start/sizes in 512byte sectors */ __u64 devstart; /* address on backup device/file of data */ __u64 arraystart; __u64 length; __u32 sb_csum; /* csum of preceeding bytes. */ __u32 pad1; __u64 devstart2; /* offset in to data of second section */ __u64 arraystart2; __u64 length2; __u32 sb_csum2; /* csum of preceeding bytes. */ __u8 pad[512-68-32]; } __attribute__((aligned(512))) bsb, bsb2; static __u32 bsb_csum(char *buf, int len) { int i; int csum = 0; for (i = 0; i < len; i++) csum = (csum<<3) + buf[0]; return __cpu_to_le32(csum); } static int check_idle(struct supertype *st) { /* Check that all member arrays for this container, or the * container of this array, are idle */ char *container = (st->container_devnm[0] ? st->container_devnm : st->devnm); struct mdstat_ent *ent, *e; int is_idle = 1; ent = mdstat_read(0, 0); for (e = ent ; e; e = e->next) { if (!is_container_member(e, container)) continue; /* frozen array is not idle*/ if (e->percent >= 0 || e->metadata_version[9] == '-') { is_idle = 0; break; } } free_mdstat(ent); return is_idle; } static int freeze_container(struct supertype *st) { char *container = (st->container_devnm[0] ? st->container_devnm : st->devnm); if (!check_idle(st)) return -1; if (block_monitor(container, 1)) { pr_err("failed to freeze container\n"); return -2; } return 1; } static void unfreeze_container(struct supertype *st) { char *container = (st->container_devnm[0] ? st->container_devnm : st->devnm); unblock_monitor(container, 1); } static int freeze(struct supertype *st) { /* Try to freeze resync/rebuild on this array/container. * Return -1 if the array is busy, * return -2 container cannot be frozen, * return 0 if this kernel doesn't support 'frozen' * return 1 if it worked. */ if (st->ss->external) return freeze_container(st); else { struct mdinfo *sra = sysfs_read(-1, st->devnm, GET_VERSION); int err; char buf[SYSFS_MAX_BUF_SIZE]; if (!sra) return -1; /* Need to clear any 'read-auto' status */ if (sysfs_get_str(sra, NULL, "array_state", buf, sizeof(buf)) > 0 && strncmp(buf, "read-auto", 9) == 0) sysfs_set_str(sra, NULL, "array_state", "clean"); err = sysfs_freeze_array(sra); sysfs_free(sra); return err; } } static void unfreeze(struct supertype *st) { if (st->ss->external) return unfreeze_container(st); else { struct mdinfo *sra = sysfs_read(-1, st->devnm, GET_VERSION); char buf[SYSFS_MAX_BUF_SIZE]; if (sra && sysfs_get_str(sra, NULL, "sync_action", buf, sizeof(buf)) > 0 && strcmp(buf, "frozen\n") == 0) sysfs_set_str(sra, NULL, "sync_action", "idle"); sysfs_free(sra); } } static void wait_reshape(struct mdinfo *sra) { int fd = sysfs_get_fd(sra, NULL, "sync_action"); char action[SYSFS_MAX_BUF_SIZE]; if (fd < 0) return; while (sysfs_fd_get_str(fd, action, sizeof(action)) > 0 && strncmp(action, "reshape", 7) == 0) sysfs_wait(fd, NULL); close(fd); } static int reshape_super(struct supertype *st, struct shape *shape, struct context *c) { /* nothing extra to check in the native case */ if (!st->ss->external) return 0; if (!st->ss->reshape_super || !st->ss->manage_reshape) { pr_err("%s metadata does not support reshape\n", st->ss->name); return 1; } return st->ss->reshape_super(st, shape, c); } /** * reshape_super_size() - Reshape array, size only. * * @st: supertype. * @devname: device name. * @size: component size. * @dir metadata changes direction * Returns: 0 on success, 1 otherwise. * * This function is solely used to change size of the volume. * Setting size is not valid for container. * Size is only change that can be rolled back, thus the @dir param. */ static int reshape_super_size(struct supertype *st, char *devname, unsigned long long size, change_dir_t direction, struct context *c) { struct shape shape = {0}; shape.level = UnSet; shape.layout = UnSet; shape.delta_disks = UnSet; shape.dev = devname; shape.size = size; shape.direction = direction; return reshape_super(st, &shape, c); } /** * reshape_super_non_size() - Reshape array, non size changes. * * @st: supertype. * @devname: device name. * @info: superblock info. * Returns: 0 on success, 1 otherwise. * * This function is used for any external array changes but size. * It handles both volumes and containers. * For changes other than size, rollback is not possible. */ static int reshape_super_non_size(struct supertype *st, char *devname, struct mdinfo *info, struct context *c) { struct shape shape = {0}; /* Size already set to zero, not updating size */ shape.level = info->new_level; shape.layout = info->new_layout; shape.chunk = info->new_chunk; shape.raiddisks = info->array.raid_disks; shape.delta_disks = info->delta_disks; shape.dev = devname; /* Rollback not possible for non size changes */ shape.direction = APPLY_METADATA_CHANGES; return reshape_super(st, &shape, c); } static void sync_metadata(struct supertype *st) { if (st->ss->external) { if (st->update_tail) { flush_metadata_updates(st); st->update_tail = &st->updates; } else st->ss->sync_metadata(st); } } static int subarray_set_num(char *container, struct mdinfo *sra, char *name, int n) { /* when dealing with external metadata subarrays we need to be * prepared to handle EAGAIN. The kernel may need to wait for * mdmon to mark the array active so the kernel can handle * allocations/writeback when preparing the reshape action * (md_allow_write()). We temporarily disable safe_mode_delay * to close a race with the array_state going clean before the * next write to raid_disks / stripe_cache_size */ char safe[SYSFS_MAX_BUF_SIZE]; int rc; /* only 'raid_disks' and 'stripe_cache_size' trigger md_allow_write */ if (!container || (strcmp(name, "raid_disks") != 0 && strcmp(name, "stripe_cache_size") != 0)) return sysfs_set_num(sra, NULL, name, n); rc = sysfs_get_str(sra, NULL, "safe_mode_delay", safe, sizeof(safe)); if (rc <= 0) return -1; sysfs_set_num(sra, NULL, "safe_mode_delay", 0); rc = sysfs_set_num(sra, NULL, name, n); if (rc < 0 && errno == EAGAIN) { ping_monitor(container); /* if we get EAGAIN here then the monitor is not active * so stop trying */ rc = sysfs_set_num(sra, NULL, name, n); } sysfs_set_str(sra, NULL, "safe_mode_delay", safe); return rc; } int start_reshape(struct mdinfo *sra, int already_running, int before_data_disks, int data_disks, struct supertype *st) { int err; unsigned long long sync_max_to_set; sysfs_set_num(sra, NULL, "suspend_lo", 0x7FFFFFFFFFFFFFFFULL); err = sysfs_set_num(sra, NULL, "suspend_hi", sra->reshape_progress); err = err ?: sysfs_set_num(sra, NULL, "suspend_lo", sra->reshape_progress); if (before_data_disks <= data_disks) sync_max_to_set = sra->reshape_progress / data_disks; else sync_max_to_set = (sra->component_size * data_disks - sra->reshape_progress) / data_disks; if (!already_running) sysfs_set_num(sra, NULL, "sync_min", sync_max_to_set); if (st->ss->external) err = err ?: sysfs_set_num(sra, NULL, "sync_max", sync_max_to_set); else err = err ?: sysfs_set_str(sra, NULL, "sync_max", "max"); if (!already_running && err == 0) { int cnt = 5; do { err = sysfs_set_str(sra, NULL, "sync_action", "reshape"); if (err) sleep_for(1, 0, true); } while (err && errno == EBUSY && cnt-- > 0); } return err; } void abort_reshape(struct mdinfo *sra) { sysfs_set_str(sra, NULL, "sync_action", "idle"); /* * Prior to kernel commit: 23ddff3792f6 ("md: allow suspend_lo and * suspend_hi to decrease as well as increase.") * you could only increase suspend_{lo,hi} unless the region they * covered was empty. So to reset to 0, you need to push suspend_lo * up past suspend_hi first. So to maximize the chance of mdadm * working on all kernels, we want to keep doing that. */ sysfs_set_num(sra, NULL, "suspend_lo", 0x7FFFFFFFFFFFFFFFULL); sysfs_set_num(sra, NULL, "suspend_hi", 0); sysfs_set_num(sra, NULL, "suspend_lo", 0); sysfs_set_num(sra, NULL, "sync_min", 0); // It isn't safe to reset sync_max as we aren't monitoring. // Array really should be stopped at this point. } int remove_disks_for_takeover(struct supertype *st, struct mdinfo *sra, int layout) { int nr_of_copies; struct mdinfo *remaining; int slot; if (st->ss->external) { int rv = 0; struct mdinfo *arrays = st->ss->container_content(st, NULL); /* * containter_content returns list of arrays in container * If arrays->next is not NULL it means that there are * 2 arrays in container and operation should be blocked */ if (arrays) { if (arrays->next) rv = 1; sysfs_free(arrays); if (rv) { pr_err("Error. Cannot perform operation on %s- for this operation " "it MUST be single array in container\n", st->devnm); return rv; } } } if (sra->array.level == 10) nr_of_copies = layout & 0xff; else if (sra->array.level == 1) nr_of_copies = sra->array.raid_disks; else return 1; remaining = sra->devs; sra->devs = NULL; /* for each 'copy', select one device and remove from the list. */ for (slot = 0; slot < sra->array.raid_disks; slot += nr_of_copies) { struct mdinfo **diskp; int found = 0; /* Find a working device to keep */ for (diskp = &remaining; *diskp ; diskp = &(*diskp)->next) { struct mdinfo *disk = *diskp; if (disk->disk.raid_disk < slot) continue; if (disk->disk.raid_disk >= slot + nr_of_copies) continue; if (disk->disk.state & (1<disk.state & (1<disk.state & (1<next; disk->next = sra->devs; sra->devs = disk; found = 1; break; } if (!found) break; } if (slot < sra->array.raid_disks) { /* didn't find all slots */ struct mdinfo **e; e = &remaining; while (*e) e = &(*e)->next; *e = sra->devs; sra->devs = remaining; return 1; } /* Remove all 'remaining' devices from the array */ while (remaining) { struct mdinfo *sd = remaining; remaining = sd->next; sysfs_set_str(sra, sd, "state", "faulty"); sysfs_set_str(sra, sd, "slot", STR_COMMON_NONE); /* for external metadata disks should be removed in mdmon */ if (!st->ss->external) sysfs_set_str(sra, sd, "state", "remove"); sd->disk.state |= (1<disk.state &= ~(1<next = sra->devs; sra->devs = sd; } return 0; } void reshape_free_fdlist(int *fdlist, unsigned long long *offsets, int size) { int i; for (i = 0; i < size; i++) if (fdlist[i] >= 0) close(fdlist[i]); free(fdlist); free(offsets); } int reshape_prepare_fdlist(char *devname, struct mdinfo *sra, int raid_disks, int nrdisks, unsigned long blocks, char *backup_file, int *fdlist, unsigned long long *offsets) { int d = 0; struct mdinfo *sd; enable_fds(nrdisks); for (d = 0; d <= nrdisks; d++) fdlist[d] = -1; d = raid_disks; for (sd = sra->devs; sd; sd = sd->next) { if (sd->disk.state & (1<disk.state & (1<disk.raid_disk < raid_disks) { char *dn = map_dev(sd->disk.major, sd->disk.minor, 1); fdlist[sd->disk.raid_disk] = dev_open(dn, O_RDONLY); offsets[sd->disk.raid_disk] = sd->data_offset*512; if (fdlist[sd->disk.raid_disk] < 0) { pr_err("%s: cannot open component %s\n", devname, dn ? dn : "-unknown-"); d = -1; goto release; } } else if (backup_file == NULL) { /* spare */ char *dn = map_dev(sd->disk.major, sd->disk.minor, 1); fdlist[d] = dev_open(dn, O_RDWR); offsets[d] = (sd->data_offset + sra->component_size - blocks - 8)*512; if (fdlist[d] < 0) { pr_err("%s: cannot open component %s\n", devname, dn ? dn : "-unknown-"); d = -1; goto release; } d++; } } release: return d; } int reshape_open_backup_file(char *backup_file, int fd, char *devname, long blocks, int *fdlist, unsigned long long *offsets, char *sys_name, int restart) { /* Return 1 on success, 0 on any form of failure */ /* need to check backup file is large enough */ char buf[512]; struct stat stb; unsigned int dev; int i; *fdlist = open(backup_file, O_RDWR|O_CREAT|(restart ? O_TRUNC : O_EXCL), S_IRUSR | S_IWUSR); *offsets = 8 * 512; if (*fdlist < 0) { pr_err("%s: cannot create backup file %s: %s\n", devname, backup_file, strerror(errno)); return 0; } /* Guard against backup file being on array device. * If array is partitioned or if LVM etc is in the * way this will not notice, but it is better than * nothing. */ if (fstat(*fdlist, &stb) != 0) goto error; dev = stb.st_dev; if (fstat(fd, &stb) != 0) goto error; if (stb.st_rdev == dev) { pr_err("backup file must NOT be on the array being reshaped.\n"); goto error; } memset(buf, 0, 512); for (i=0; i < blocks + 8 ; i++) { if (write(*fdlist, buf, 512) != 512) { pr_err("%s: cannot create backup file %s: %s\n", devname, backup_file, strerror(errno)); return 0; } } if (fsync(*fdlist) != 0) { pr_err("%s: cannot create backup file %s: %s\n", devname, backup_file, strerror(errno)); return 0; } if (!restart && strncmp(backup_file, MAP_DIR, strlen(MAP_DIR)) != 0) { char *bu = make_backup(sys_name); if (symlink(backup_file, bu)) pr_err("Recording backup file in " MAP_DIR " failed: %s\n", strerror(errno)); free(bu); } return 1; error: close(*fdlist); return 0; } unsigned long compute_backup_blocks(int nchunk, int ochunk, unsigned int ndata, unsigned int odata) { unsigned long a, b, blocks; /* So how much do we need to backup. * We need an amount of data which is both a whole number of * old stripes and a whole number of new stripes. * So LCM for (chunksize*datadisks). */ a = (ochunk/512) * odata; b = (nchunk/512) * ndata; /* Find GCD */ a = GCD(a, b); /* LCM == product / GCD */ blocks = (unsigned long)(ochunk/512) * (unsigned long)(nchunk/512) * odata * ndata / a; return blocks; } char *analyse_change(char *devname, struct mdinfo *info, struct reshape *re) { /* Based on the current array state in info->array and * the changes in info->new_* etc, determine: * - whether the change is possible * - Intermediate level/raid_disks/layout * - whether a restriping reshape is needed * - number of sectors in minimum change unit. This * will cover a whole number of stripes in 'before' and * 'after'. * * Return message if the change should be rejected * NULL if the change can be achieved * * This can be called as part of starting a reshape, or * when assembling an array that is undergoing reshape. */ int near, far, offset, copies; int new_disks; int old_chunk, new_chunk; /* delta_parity records change in number of devices * caused by level change */ int delta_parity = 0; memset(re, 0, sizeof(*re)); /* If a new level not explicitly given, we assume no-change */ if (info->new_level == UnSet) info->new_level = info->array.level; if (info->new_chunk) switch (info->new_level) { case 0: case 4: case 5: case 6: case 10: /* chunk size is meaningful, must divide component_size * evenly */ if (info->component_size % (info->new_chunk/512)) { unsigned long long shrink = info->component_size; shrink &= ~(unsigned long long)(info->new_chunk/512-1); pr_err("New chunk size (%dK) does not evenly divide device size (%lluk)\n", info->new_chunk/1024, info->component_size/2); pr_err("After shrinking any filesystem, \"mdadm --grow %s --size %llu\"\n", devname, shrink/2); pr_err("will shrink the array so the given chunk size would work.\n"); return ""; } break; default: return "chunk size not meaningful for this level"; } else info->new_chunk = info->array.chunk_size; switch (info->array.level) { default: return "No reshape is possibly for this RAID level"; case LEVEL_LINEAR: if (info->delta_disks != UnSet) return "Only --add is supported for LINEAR, setting --raid-disks is not needed"; else return "Only --add is supported for LINEAR, other --grow options are not meaningful"; case 1: /* RAID1 can convert to RAID1 with different disks, or * raid5 with 2 disks, or * raid0 with 1 disk */ if (info->new_level > 1 && (info->component_size & 7)) return "Cannot convert RAID1 of this size - reduce size to multiple of 4K first."; if (info->new_level == 0) { if (info->delta_disks != UnSet && info->delta_disks != 0) return "Cannot change number of disks with RAID1->RAID0 conversion"; re->level = 0; re->before.data_disks = 1; re->after.data_disks = 1; return NULL; } if (info->new_level == 1) { if (info->delta_disks == UnSet) /* Don't know what to do */ return "no change requested for Growing RAID1"; re->level = 1; return NULL; } if (info->array.raid_disks != 2 && info->new_level == 5) return "Can only convert a 2-device array to RAID5"; if (info->array.raid_disks == 2 && info->new_level == 5) { re->level = 5; re->before.data_disks = 1; if (info->delta_disks != UnSet && info->delta_disks != 0) re->after.data_disks = 1 + info->delta_disks; else re->after.data_disks = 1; if (re->after.data_disks < 1) return "Number of disks too small for RAID5"; re->before.layout = ALGORITHM_LEFT_SYMMETRIC; info->array.chunk_size = 65536; break; } /* Could do some multi-stage conversions, but leave that to * later. */ return "Impossibly level change request for RAID1"; case 10: /* RAID10 can be converted from near mode to * RAID0 by removing some devices. * It can also be reshaped if the kernel supports * new_data_offset. */ switch (info->new_level) { case 0: if ((info->array.layout & ~0xff) != 0x100) return "Cannot Grow RAID10 with far/offset layout"; /* * number of devices must be multiple of * number of copies */ if (info->array.raid_disks % (info->array.layout & 0xff)) return "RAID10 layout too complex for Grow operation"; new_disks = (info->array.raid_disks / (info->array.layout & 0xff)); if (info->delta_disks == UnSet) info->delta_disks = (new_disks - info->array.raid_disks); if (info->delta_disks != new_disks - info->array.raid_disks) return "New number of raid-devices impossible for RAID10"; if (info->new_chunk && info->new_chunk != info->array.chunk_size) return "Cannot change chunk-size with RAID10 Grow"; /* looks good */ re->level = 0; re->before.data_disks = new_disks; re->after.data_disks = re->before.data_disks; return NULL; case 10: near = info->array.layout & 0xff; far = (info->array.layout >> 8) & 0xff; offset = info->array.layout & 0x10000; if (far > 1 && !offset) return "Cannot reshape RAID10 in far-mode"; copies = near * far; old_chunk = info->array.chunk_size * far; if (info->new_layout == UnSet) info->new_layout = info->array.layout; else { near = info->new_layout & 0xff; far = (info->new_layout >> 8) & 0xff; offset = info->new_layout & 0x10000; if (far > 1 && !offset) return "Cannot reshape RAID10 to far-mode"; if (near * far != copies) return "Cannot change number of copies when reshaping RAID10"; } if (info->delta_disks == UnSet) info->delta_disks = 0; new_disks = (info->array.raid_disks + info->delta_disks); new_chunk = info->new_chunk * far; re->level = 10; re->before.layout = info->array.layout; re->before.data_disks = info->array.raid_disks; re->after.layout = info->new_layout; re->after.data_disks = new_disks; /* For RAID10 we don't do backup but do allow reshape, * so set backup_blocks to INVALID_SECTORS rather than * zero. * And there is no need to synchronise stripes on both * 'old' and 'new'. So the important * number is the minimum data_offset difference * which is the larger of (offset copies * chunk). */ re->backup_blocks = INVALID_SECTORS; re->min_offset_change = max(old_chunk, new_chunk) / 512; if (new_disks < re->before.data_disks && info->space_after < re->min_offset_change) /* Reduce component size by one chunk */ re->new_size = (info->component_size - re->min_offset_change); else re->new_size = info->component_size; re->new_size = re->new_size * new_disks / copies; return NULL; default: return "RAID10 can only be changed to RAID0"; } case 0: /* RAID0 can be converted to RAID10, or to RAID456 */ if (info->new_level == 10) { if (info->new_layout == UnSet && info->delta_disks == UnSet) { /* Assume near=2 layout */ info->new_layout = 0x102; info->delta_disks = info->array.raid_disks; } if (info->new_layout == UnSet) { int copies = 1 + (info->delta_disks / info->array.raid_disks); if (info->array.raid_disks * (copies-1) != info->delta_disks) return "Impossible number of devices for RAID0->RAID10"; info->new_layout = 0x100 + copies; } if (info->delta_disks == UnSet) { int copies = info->new_layout & 0xff; if (info->new_layout != 0x100 + copies) return "New layout impossible for RAID0->RAID10";; info->delta_disks = (copies - 1) * info->array.raid_disks; } if (info->new_chunk && info->new_chunk != info->array.chunk_size) return "Cannot change chunk-size with RAID0->RAID10"; /* looks good */ re->level = 10; re->before.data_disks = (info->array.raid_disks + info->delta_disks); re->after.data_disks = re->before.data_disks; re->before.layout = info->new_layout; return NULL; } /* RAID0 can also covert to RAID0/4/5/6 by first converting to * a raid4 style layout of the final level. */ switch (info->new_level) { case 4: delta_parity = 1; case 0: re->level = 4; re->before.layout = 0; break; case 5: delta_parity = 1; re->level = 5; re->before.layout = ALGORITHM_PARITY_N; if (info->new_layout == UnSet) info->new_layout = map_name(r5layout, "default"); break; case 6: delta_parity = 2; re->level = 6; re->before.layout = ALGORITHM_PARITY_N; if (info->new_layout == UnSet) info->new_layout = map_name(r6layout, "default"); break; default: return "Impossible level change requested"; } re->before.data_disks = info->array.raid_disks; /* determining 'after' layout happens outside this 'switch' */ break; case 4: info->array.layout = ALGORITHM_PARITY_N; case 5: switch (info->new_level) { case 0: delta_parity = -1; case 4: re->level = info->array.level; re->before.data_disks = info->array.raid_disks - 1; re->before.layout = info->array.layout; break; case 5: re->level = 5; re->before.data_disks = info->array.raid_disks - 1; re->before.layout = info->array.layout; break; case 6: delta_parity = 1; re->level = 6; re->before.data_disks = info->array.raid_disks - 1; switch (info->array.layout) { case ALGORITHM_LEFT_ASYMMETRIC: re->before.layout = ALGORITHM_LEFT_ASYMMETRIC_6; break; case ALGORITHM_RIGHT_ASYMMETRIC: re->before.layout = ALGORITHM_RIGHT_ASYMMETRIC_6; break; case ALGORITHM_LEFT_SYMMETRIC: re->before.layout = ALGORITHM_LEFT_SYMMETRIC_6; break; case ALGORITHM_RIGHT_SYMMETRIC: re->before.layout = ALGORITHM_RIGHT_SYMMETRIC_6; break; case ALGORITHM_PARITY_0: re->before.layout = ALGORITHM_PARITY_0_6; break; case ALGORITHM_PARITY_N: re->before.layout = ALGORITHM_PARITY_N_6; break; default: return "Cannot convert an array with this layout"; } break; case 1: if (info->array.raid_disks != 2) return "Can only convert a 2-device array to RAID1"; if (info->delta_disks != UnSet && info->delta_disks != 0) return "Cannot set raid_disk when converting RAID5->RAID1"; re->level = 1; info->new_chunk = 0; return NULL; default: return "Impossible level change requested"; } break; case 6: switch (info->new_level) { case 4: case 5: delta_parity = -1; case 6: re->level = 6; re->before.data_disks = info->array.raid_disks - 2; re->before.layout = info->array.layout; break; default: return "Impossible level change requested"; } break; } /* If we reached here then it looks like a re-stripe is * happening. We have determined the intermediate level * and initial raid_disks/layout and stored these in 're'. * * We need to deduce the final layout that can be atomically * converted to the end state. */ switch (info->new_level) { case 0: /* We can only get to RAID0 from RAID4 or RAID5 * with appropriate layout and one extra device */ if (re->level != 4 && re->level != 5) return "Cannot covert to RAID0 from this level"; switch (re->level) { case 4: re->before.layout = 0; re->after.layout = 0; break; case 5: re->after.layout = ALGORITHM_PARITY_N; break; } break; case 4: /* We can only get to RAID4 from RAID5 */ if (re->level != 4 && re->level != 5) return "Cannot convert to RAID4 from this level"; switch (re->level) { case 4: re->after.layout = 0; break; case 5: re->after.layout = ALGORITHM_PARITY_N; break; } break; case 5: /* We get to RAID5 from RAID5 or RAID6 */ if (re->level != 5 && re->level != 6) return "Cannot convert to RAID5 from this level"; switch (re->level) { case 5: if (info->new_layout == UnSet) re->after.layout = re->before.layout; else re->after.layout = info->new_layout; break; case 6: if (info->new_layout == UnSet) info->new_layout = re->before.layout; /* after.layout needs to be raid6 version of new_layout */ if (info->new_layout == ALGORITHM_PARITY_N) re->after.layout = ALGORITHM_PARITY_N; else { char layout[40]; char *ls = map_num(r5layout, info->new_layout); int l; if (ls) { /* Current RAID6 layout has a RAID5 * equivalent - good */ snprintf(layout, 40, "%s-6", ls); l = map_name(r6layout, layout); if (l == UnSet) return "Cannot find RAID6 layout to convert to"; } else { /* Current RAID6 has no equivalent. * If it is already a '-6' layout we * can leave it unchanged, else we must * fail */ ls = map_num(r6layout, info->new_layout); if (!ls || strcmp(ls+strlen(ls)-2, "-6") != 0) return "Please specify new layout"; l = info->new_layout; } re->after.layout = l; } } break; case 6: /* We must already be at level 6 */ if (re->level != 6) return "Impossible level change"; if (info->new_layout == UnSet) re->after.layout = info->array.layout; else re->after.layout = info->new_layout; break; default: return "Impossible level change requested"; } if (info->delta_disks == UnSet) info->delta_disks = delta_parity; re->after.data_disks = (re->before.data_disks + info->delta_disks - delta_parity); switch (re->level) { case 6: re->parity = 2; break; case 4: case 5: re->parity = 1; break; default: re->parity = 0; break; } /* So we have a restripe operation, we need to calculate the number * of blocks per reshape operation. */ re->new_size = info->component_size * re->before.data_disks; if (info->new_chunk == 0) info->new_chunk = info->array.chunk_size; if (re->after.data_disks == re->before.data_disks && re->after.layout == re->before.layout && info->new_chunk == info->array.chunk_size) { /* Nothing to change, can change level immediately. */ re->level = info->new_level; re->backup_blocks = 0; return NULL; } if (re->after.data_disks == 1 && re->before.data_disks == 1) { /* chunk and layout changes make no difference */ re->level = info->new_level; re->backup_blocks = 0; return NULL; } re->backup_blocks = compute_backup_blocks( info->new_chunk, info->array.chunk_size, re->after.data_disks, re->before.data_disks); re->min_offset_change = re->backup_blocks / re->before.data_disks; re->new_size = info->component_size * re->after.data_disks; return NULL; } static int set_array_size(struct supertype *st, struct mdinfo *sra, char *text_version) { struct mdinfo *info; char *subarray; int ret_val = -1; if ((st == NULL) || (sra == NULL)) return ret_val; if (text_version == NULL) text_version = sra->text_version; subarray = strchr(text_version + 1, '/')+1; info = st->ss->container_content(st, subarray); if (info) { unsigned long long current_size = 0; unsigned long long new_size = info->custom_array_size/2; if (sysfs_get_ll(sra, NULL, "array_size", ¤t_size) == 0 && new_size > current_size) { if (sysfs_set_num(sra, NULL, "array_size", new_size) < 0) dprintf("Error: Cannot set array size"); else { ret_val = 0; dprintf("Array size changed"); } dprintf_cont(" from %llu to %llu.\n", current_size, new_size); } sysfs_free(info); } else dprintf("Error: set_array_size(): info pointer in NULL\n"); return ret_val; } static int reshape_array(char *container, int fd, char *devname, struct supertype *st, struct mdinfo *info, int force, struct mddev_dev *devlist, unsigned long long data_offset, char *backup_file, int verbose, int forked, int restart, int freeze_reshape); static int reshape_container(char *container, char *devname, int mdfd, struct supertype *st, struct mdinfo *info, struct context *c, int forked, int restart); /** * prepare_external_reshape() - prepares update on external metadata if supported. * @devname: Device name. * @subarray: Subarray. * @st: Supertype. * @container: Container. * @cfd: Container file descriptor. * * Function checks that the requested reshape is supported on external metadata, * and performs an initial check that the container holds the pre-requisite * spare devices (mdmon owns final validation). * * Return: 0 on success, else 1 */ static int prepare_external_reshape(char *devname, char *subarray, struct supertype *st, char *container, const int cfd) { struct mdinfo *cc = NULL; struct mdinfo *content = NULL; if (st->ss->load_container(st, cfd, NULL)) { pr_err("Cannot read superblock for %s\n", devname); return 1; } if (!st->ss->container_content) return 1; cc = st->ss->container_content(st, subarray); for (content = cc; content ; content = content->next) { /* * check if reshape is allowed based on metadata * indications stored in content.array.status */ if (is_bit_set(&content->array.state, MD_SB_BLOCK_VOLUME) || is_bit_set(&content->array.state, MD_SB_BLOCK_CONTAINER_RESHAPE)) { pr_err("Cannot reshape arrays in container with unsupported metadata: %s(%s)\n", devname, container); goto error; } if (content->consistency_policy == CONSISTENCY_POLICY_PPL) { pr_err("Operation not supported when ppl consistency policy is enabled\n"); goto error; } if (content->consistency_policy == CONSISTENCY_POLICY_BITMAP) { pr_err("Operation not supported when write-intent bitmap consistency policy is enabled\n"); goto error; } } sysfs_free(cc); if (mdmon_running(container)) st->update_tail = &st->updates; return 0; error: sysfs_free(cc); return 1; } int Grow_reshape(char *devname, int fd, struct mddev_dev *devlist, struct context *c, struct shape *s) { /* Make some changes in the shape of an array. * The kernel must support the change. * * There are three different changes. Each can trigger * a resync or recovery so we freeze that until we have * requested everything (if kernel supports freezing - 2.6.30). * The steps are: * - change size (i.e. component_size) * - change level * - change layout/chunksize/ndisks * * The last can require a reshape. It is different on different * levels so we need to check the level before actioning it. * Some times the level change needs to be requested after the * reshape (e.g. raid6->raid5, raid5->raid0) * */ struct mdu_array_info_s array; int rv = 0; struct supertype *st; char *subarray = NULL; int frozen = 0; int changed = 0; char *container = NULL; int cfd = -1; struct mddev_dev *dv; int added_disks; struct mdinfo info; struct mdinfo *sra = NULL; if (md_get_array_info(fd, &array) < 0) { pr_err("%s is not an active md array - aborting\n", devname); return 1; } if (s->level != UnSet && s->chunk) { pr_err("Cannot change array level in the same operation as changing chunk size.\n"); return 1; } if (s->data_offset != INVALID_SECTORS && array.level != 10 && (array.level < 4 || array.level > 6)) { pr_err("--grow --data-offset not yet supported\n"); return 1; } if (s->size > 0 && (s->chunk || s->level!= UnSet || s->layout_str || s->raiddisks)) { pr_err("cannot change component size at the same time as other changes.\n" " Change size first, then check data is intact before making other changes.\n"); return 1; } if (array.level > 1 && s->size > 1 && (unsigned long long) (array.chunk_size / 1024) > s->size) { pr_err("component size must be larger than chunk size.\n"); return 1; } st = super_by_fd(fd, &subarray); if (!st) { pr_err("Unable to determine metadata format for %s\n", devname); return 1; } if (s->raiddisks > st->max_devs) { pr_err("Cannot increase raid-disks on this array beyond %d\n", st->max_devs); return 1; } if (s->level == 0 && (array.state & (1 << MD_SB_BITMAP_PRESENT)) && !(array.state & (1 << MD_SB_CLUSTERED)) && !st->ss->external) { array.state &= ~(1 << MD_SB_BITMAP_PRESENT); if (md_set_array_info(fd, &array) != 0) { pr_err("failed to remove internal bitmap.\n"); return 1; } } if (st->ss->external) { if (subarray) { container = st->container_devnm; cfd = open_dev_excl(st->container_devnm); } else { container = st->devnm; close(fd); cfd = open_dev_excl(st->devnm); fd = cfd; } if (cfd < 0) { pr_err("Unable to open container for %s\n", devname); free(subarray); return 1; } rv = prepare_external_reshape(devname, subarray, st, container, cfd); if (rv > 0) { free(subarray); close(cfd); goto release; } if (s->raiddisks && subarray) { pr_err("--raid-devices operation can be performed on a container only\n"); close(cfd); free(subarray); return 1; } } added_disks = 0; for (dv = devlist; dv; dv = dv->next) added_disks++; if (s->raiddisks > array.raid_disks && array.spare_disks + added_disks < (s->raiddisks - array.raid_disks) && !c->force) { pr_err("Need %d spare%s to avoid degraded array, and only have %d.\n" " Use --force to over-ride this check.\n", s->raiddisks - array.raid_disks, s->raiddisks - array.raid_disks == 1 ? "" : "s", array.spare_disks + added_disks); return 1; } sra = sysfs_read(fd, NULL, GET_LEVEL | GET_DISKS | GET_DEVS | GET_STATE | GET_VERSION); if (sra) { if (st->ss->external && subarray == NULL) { array.level = LEVEL_CONTAINER; sra->array.level = LEVEL_CONTAINER; } } else { pr_err("failed to read sysfs parameters for %s\n", devname); return 1; } frozen = freeze(st); if (frozen < -1) { /* freeze() already spewed the reason */ sysfs_free(sra); return 1; } else if (frozen < 0) { pr_err("%s is performing resync/recovery and cannot be reshaped\n", devname); sysfs_free(sra); return 1; } /* ========= set size =============== */ if (s->size > 0 && (s->size == MAX_SIZE || s->size != (unsigned)array.size)) { unsigned long long orig_size = get_component_size(fd) / 2; unsigned long long min_csize; struct mdinfo *mdi; int raid0_takeover = 0; if (orig_size == 0) orig_size = (unsigned) array.size; if (orig_size == 0) { pr_err("Cannot set device size in this type of array.\n"); rv = 1; goto release; } if (array.level == 0) { pr_err("Component size change is not supported for RAID0\n"); rv = 1; goto release; } if (reshape_super_size(st, devname, s->size, APPLY_METADATA_CHANGES, c)) { rv = 1; goto release; } sync_metadata(st); if (st->ss->external) { /* metadata can have size limitation * update size value according to metadata information */ struct mdinfo *sizeinfo = st->ss->container_content(st, subarray); if (sizeinfo) { unsigned long long new_size = sizeinfo->custom_array_size/2; int data_disks = get_data_disks( sizeinfo->array.level, sizeinfo->array.layout, sizeinfo->array.raid_disks); new_size /= data_disks; dprintf("Metadata size correction from %llu to %llu (%llu)\n", orig_size, new_size, new_size * data_disks); s->size = new_size; sysfs_free(sizeinfo); } } /* Update the size of each member device in case * they have been resized. This will never reduce * below the current used-size. The "size" attribute * understands '0' to mean 'max'. */ min_csize = 0; for (mdi = sra->devs; mdi; mdi = mdi->next) { sysfs_set_num(sra, mdi, "size", s->size == MAX_SIZE ? 0 : s->size); if (array.not_persistent == 0 && array.major_version == 0 && get_linux_version() < 3001000) { /* Dangerous to allow size to exceed 2TB */ unsigned long long csize; if (sysfs_get_ll(sra, mdi, "size", &csize) == 0) { if (csize >= 2ULL*1024*1024*1024) csize = 2ULL*1024*1024*1024; if ((min_csize == 0 || (min_csize > csize))) min_csize = csize; } } } if (min_csize && s->size > min_csize) { pr_err("Cannot safely make this array use more than 2TB per device on this kernel.\n"); rv = 1; goto size_change_error; } if (min_csize && s->size == MAX_SIZE) { /* Don't let the kernel choose a size - it will get * it wrong */ pr_err("Limited v0.90 array to 2TB per device\n"); s->size = min_csize; } if (st->ss->external) { if (sra->array.level == 0) { rv = sysfs_set_str(sra, NULL, "level", "raid5"); if (!rv) { raid0_takeover = 1; /* get array parameters after takeover * to change one parameter at time only */ rv = md_get_array_info(fd, &array); } } /* make sure mdmon is * aware of the new level */ if (!mdmon_running(st->container_devnm)) start_mdmon(st->container_devnm); ping_monitor(container); if (wait_for_mdmon(st->container_devnm) != MDADM_STATUS_SUCCESS) { pr_err("No mdmon found. Grow cannot continue.\n"); goto release; } } if (s->size == MAX_SIZE) s->size = 0; array.size = s->size; rv = sysfs_set_num(sra, NULL, "component_size", s->size); /* * For native metadata, md/array_size is updated by kernel, * for external management update it here. */ if (st->ss->external && rv == MDADM_STATUS_SUCCESS) rv = set_array_size(st, sra, sra->text_version); if (raid0_takeover) { /* do not recync non-existing parity, * we will drop it anyway */ sysfs_set_str(sra, NULL, "sync_action", "frozen"); /* go back to raid0, drop parity disk */ sysfs_set_str(sra, NULL, "level", "raid0"); md_get_array_info(fd, &array); } size_change_error: if (rv != 0) { int err = errno; /* restore metadata */ if (reshape_super_size(st, devname, orig_size, ROLLBACK_METADATA_CHANGES, c) == 0) sync_metadata(st); pr_err("Cannot set device size for %s: %s\n", devname, strerror(err)); if (err == EBUSY && (array.state & (1<assume_clean) { /* This will fail on kernels older than 3.0 unless * a backport has been arranged. */ if (sra == NULL || sysfs_set_str(sra, NULL, "resync_start", STR_COMMON_NONE) < 0) pr_err("--assume-clean not supported with --grow on this kernel\n"); } md_get_array_info(fd, &array); s->size = get_component_size(fd)/2; if (s->size == 0) s->size = array.size; if (c->verbose >= 0) { if (s->size == orig_size) pr_err("component size of %s unchanged at %lluK\n", devname, s->size); else pr_err("component size of %s has been set to %lluK\n", devname, s->size); } changed = 1; } else if (!is_container(array.level)) { s->size = get_component_size(fd)/2; if (s->size == 0) s->size = array.size; } /* See if there is anything else to do */ if ((s->level == UnSet || s->level == array.level) && (s->layout_str == NULL) && (s->chunk == 0 || s->chunk == array.chunk_size) && s->data_offset == INVALID_SECTORS && (s->raiddisks == 0 || s->raiddisks == array.raid_disks)) { /* Nothing more to do */ if (!changed && c->verbose >= 0) pr_err("%s: no change requested\n", devname); goto release; } /* ========= check for Raid10/Raid1 -> Raid0 conversion =============== * current implementation assumes that following conditions must be met: * - RAID10: * - far_copies == 1 * - near_copies == 2 */ if ((s->level == 0 && array.level == 10 && sra && array.layout == ((1 << 8) + 2) && !(array.raid_disks & 1)) || (s->level == 0 && array.level == 1 && sra)) { int err; err = remove_disks_for_takeover(st, sra, array.layout); if (err) { dprintf("Array cannot be reshaped\n"); if (cfd > -1) close(cfd); rv = 1; goto release; } /* Make sure mdmon has seen the device removal * and updated metadata before we continue with * level change */ if (container) ping_monitor(container); } memset(&info, 0, sizeof(info)); info.array = array; if (sysfs_init(&info, fd, NULL)) { pr_err("failed to initialize sysfs.\n"); rv = 1; goto release; } strcpy(info.text_version, sra->text_version); info.component_size = s->size*2; info.new_level = s->level; info.new_chunk = s->chunk * 1024; if (is_container(info.array.level)) { info.delta_disks = UnSet; info.array.raid_disks = s->raiddisks; } else if (s->raiddisks) info.delta_disks = s->raiddisks - info.array.raid_disks; else info.delta_disks = UnSet; if (s->layout_str == NULL) { info.new_layout = UnSet; if (info.array.level == 6 && (info.new_level == 6 || info.new_level == UnSet) && info.array.layout >= 16) { pr_err("%s has a non-standard layout. If you wish to preserve this\n", devname); cont_err("during the reshape, please specify --layout=preserve\n"); cont_err("If you want to change it, specify a layout or use --layout=normalise\n"); rv = 1; goto release; } } else if (strcmp(s->layout_str, "normalise") == 0 || strcmp(s->layout_str, "normalize") == 0) { /* If we have a -6 RAID6 layout, remove the '-6'. */ info.new_layout = UnSet; if (info.array.level == 6 && info.new_level == UnSet) { char l[40], *h; strcpy(l, map_num_s(r6layout, info.array.layout)); h = strrchr(l, '-'); if (h && strcmp(h, "-6") == 0) { *h = 0; info.new_layout = map_name(r6layout, l); } } else { pr_err("%s is only meaningful when reshaping a RAID6 array.\n", s->layout_str); rv = 1; goto release; } } else if (strcmp(s->layout_str, "preserve") == 0) { /* This means that a non-standard RAID6 layout * is OK. * In particular: * - When reshape a RAID6 (e.g. adding a device) * which is in a non-standard layout, it is OK * to preserve that layout. * - When converting a RAID5 to RAID6, leave it in * the XXX-6 layout, don't re-layout. */ if (info.array.level == 6 && info.new_level == UnSet) info.new_layout = info.array.layout; else if (info.array.level == 5 && info.new_level == 6) { char l[40]; strcpy(l, map_num_s(r5layout, info.array.layout)); strcat(l, "-6"); info.new_layout = map_name(r6layout, l); } else { pr_err("%s in only meaningful when reshaping to RAID6\n", s->layout_str); rv = 1; goto release; } } else { int l = info.new_level; if (l == UnSet) l = info.array.level; switch (l) { case 5: info.new_layout = map_name(r5layout, s->layout_str); break; case 6: info.new_layout = map_name(r6layout, s->layout_str); break; case 10: info.new_layout = parse_layout_10(s->layout_str); break; case LEVEL_FAULTY: info.new_layout = parse_layout_faulty(s->layout_str); break; default: pr_err("layout not meaningful with this level\n"); rv = 1; goto release; } if (info.new_layout == UnSet) { pr_err("layout %s not understood for this level\n", s->layout_str); rv = 1; goto release; } } if (array.level == LEVEL_FAULTY) { if (s->level != UnSet && s->level != array.level) { pr_err("cannot change level of Faulty device\n"); rv =1 ; } if (s->chunk) { pr_err("cannot set chunksize of Faulty device\n"); rv =1 ; } if (s->raiddisks && s->raiddisks != 1) { pr_err("cannot set raid_disks of Faulty device\n"); rv =1 ; } if (s->layout_str) { if (md_get_array_info(fd, &array) != 0) { dprintf("Cannot get array information.\n"); goto release; } array.layout = info.new_layout; if (md_set_array_info(fd, &array) != 0) { pr_err("failed to set new layout\n"); rv = 1; } else if (c->verbose >= 0) printf("layout for %s set to %d\n", devname, array.layout); } } else if (is_container(array.level)) { /* This change is to be applied to every array in the * container. This is only needed when the metadata imposes * restraints of the various arrays in the container. * Currently we only know that IMSM requires all arrays * to have the same number of devices so changing the * number of devices (On-Line Capacity Expansion) must be * performed at the level of the container */ close_fd(&fd); rv = reshape_container(container, devname, -1, st, &info, c, 0, 0); frozen = 0; } else { /* get spare devices from external metadata */ if (st->ss->external) { struct mdinfo *info2; info2 = st->ss->container_content(st, subarray); if (info2) { info.array.spare_disks = info2->array.spare_disks; sysfs_free(info2); } } /* Impose these changes on a single array. First * check that the metadata is OK with the change. */ if (reshape_super_non_size(st, devname, &info, c)) { rv = 1; goto release; } sync_metadata(st); rv = reshape_array(container, fd, devname, st, &info, c->force, devlist, s->data_offset, c->backup_file, c->verbose, 0, 0, 0); frozen = 0; } release: sysfs_free(sra); if (frozen > 0) unfreeze(st); return rv; } /* verify_reshape_position() * Function checks if reshape position in metadata is not farther * than position in md. * Return value: * 0 : not valid sysfs entry * it can be caused by not started reshape, it should be started * by reshape array or raid0 array is before takeover * -1 : error, reshape position is obviously wrong * 1 : success, reshape progress correct or updated */ static int verify_reshape_position(struct mdinfo *info, int level) { int ret_val = 0; char buf[SYSFS_MAX_BUF_SIZE]; int rv; /* read sync_max, failure can mean raid0 array */ rv = sysfs_get_str(info, NULL, "sync_max", buf, sizeof(buf)); if (rv > 0) { char *ep; unsigned long long position = strtoull(buf, &ep, 0); dprintf("Read sync_max sysfs entry is: %s\n", buf); if (!(ep == buf || (*ep != 0 && *ep != '\n' && *ep != ' '))) { position *= get_data_disks(level, info->new_layout, info->array.raid_disks); if (info->reshape_progress < position) { dprintf("Corrected reshape progress (%llu) to md position (%llu)\n", info->reshape_progress, position); info->reshape_progress = position; ret_val = 1; } else if (info->reshape_progress > position) { pr_err("Fatal error: array reshape was not properly frozen (expected reshape position is %llu, but reshape progress is %llu.\n", position, info->reshape_progress); ret_val = -1; } else { dprintf("Reshape position in md and metadata are the same;"); ret_val = 1; } } } else if (rv == 0) { /* for valid sysfs entry, 0-length content * should be indicated as error */ ret_val = -1; } return ret_val; } static unsigned long long choose_offset(unsigned long long lo, unsigned long long hi, unsigned long long min, unsigned long long max) { /* Choose a new offset between hi and lo. * It must be between min and max, but * we would prefer something near the middle of hi/lo, and also * prefer to be aligned to a big power of 2. * * So we start with the middle, then for each bit, * starting at '1' and increasing, if it is set, we either * add it or subtract it if possible, preferring the option * which is furthest from the boundary. * * We stop once we get a 1MB alignment. As units are in sectors, * 1MB = 2*1024 sectors. */ unsigned long long choice = (lo + hi) / 2; unsigned long long bit = 1; for (bit = 1; bit < 2*1024; bit = bit << 1) { unsigned long long bigger, smaller; if (! (bit & choice)) continue; bigger = choice + bit; smaller = choice - bit; if (bigger > max && smaller < min) break; if (bigger > max) choice = smaller; else if (smaller < min) choice = bigger; else if (hi - bigger > smaller - lo) choice = bigger; else choice = smaller; } return choice; } static int set_new_data_offset(struct mdinfo *sra, struct supertype *st, char *devname, int delta_disks, unsigned long long data_offset, unsigned long long min, int can_fallback) { struct mdinfo *sd; int dir = 0; int err = 0; unsigned long long before, after; /* Need to find min space before and after so same is used * on all devices */ before = UINT64_MAX; after = UINT64_MAX; for (sd = sra->devs; sd; sd = sd->next) { char *dn; int dfd; int rv; struct supertype *st2; struct mdinfo info2; if (sd->disk.state & (1<disk.major, sd->disk.minor, 0); dfd = dev_open(dn, O_RDONLY); if (dfd < 0) { pr_err("%s: cannot open component %s\n", devname, dn ? dn : "-unknown-"); goto release; } st2 = dup_super(st); rv = st2->ss->load_super(st2,dfd, NULL); close(dfd); if (rv) { free(st2); pr_err("%s: cannot get superblock from %s\n", devname, dn); goto release; } st2->ss->getinfo_super(st2, &info2, NULL); st2->ss->free_super(st2); free(st2); if (info2.space_before == 0 && info2.space_after == 0) { /* Metadata doesn't support data_offset changes */ if (!can_fallback) pr_err("%s: Metadata version doesn't support data_offset changes\n", devname); goto fallback; } if (before > info2.space_before) before = info2.space_before; if (after > info2.space_after) after = info2.space_after; if (data_offset != INVALID_SECTORS) { if (dir == 0) { if (info2.data_offset == data_offset) { pr_err("%s: already has that data_offset\n", dn); goto release; } if (data_offset < info2.data_offset) dir = -1; else dir = 1; } else if ((data_offset <= info2.data_offset && dir == 1) || (data_offset >= info2.data_offset && dir == -1)) { pr_err("%s: differing data offsets on devices make this --data-offset setting impossible\n", dn); goto release; } } } if (before == UINT64_MAX) /* impossible really, there must be no devices */ return 1; for (sd = sra->devs; sd; sd = sd->next) { char *dn = map_dev(sd->disk.major, sd->disk.minor, 0); unsigned long long new_data_offset; if (sd->disk.state & (1<data_offset + min; else { if (data_offset < sd->data_offset + min) { pr_err("--data-offset too small for %s\n", dn); goto release; } new_data_offset = data_offset; } } else if (delta_disks > 0) { /* need space before */ if (before < min) { if (can_fallback) goto fallback; pr_err("Insufficient head-space for reshape on %s\n", dn); goto release; } if (data_offset == INVALID_SECTORS) new_data_offset = sd->data_offset - min; else { if (data_offset > sd->data_offset - min) { pr_err("--data-offset too large for %s\n", dn); goto release; } new_data_offset = data_offset; } } else { if (dir == 0) { /* can move up or down. If 'data_offset' * was set we would have already decided, * so just choose direction with most space. */ if (before > after) dir = -1; else dir = 1; } sysfs_set_str(sra, NULL, "reshape_direction", dir == 1 ? "backwards" : "forwards"); if (dir > 0) { /* Increase data offset */ if (after < min) { if (can_fallback) goto fallback; pr_err("Insufficient tail-space for reshape on %s\n", dn); goto release; } if (data_offset != INVALID_SECTORS && data_offset < sd->data_offset + min) { pr_err("--data-offset too small on %s\n", dn); goto release; } if (data_offset != INVALID_SECTORS) new_data_offset = data_offset; else new_data_offset = choose_offset(sd->data_offset, sd->data_offset + after, sd->data_offset + min, sd->data_offset + after); } else { /* Decrease data offset */ if (before < min) { if (can_fallback) goto fallback; pr_err("insufficient head-room on %s\n", dn); goto release; } if (data_offset != INVALID_SECTORS && data_offset > sd->data_offset - min) { pr_err("--data-offset too large on %s\n", dn); goto release; } if (data_offset != INVALID_SECTORS) new_data_offset = data_offset; else new_data_offset = choose_offset(sd->data_offset - before, sd->data_offset, sd->data_offset - before, sd->data_offset - min); } } err = sysfs_set_num(sra, sd, "new_offset", new_data_offset); if (err < 0 && errno == E2BIG) { /* try again after increasing data size to max */ err = sysfs_set_num(sra, sd, "size", 0); if (err < 0 && errno == EINVAL && !(sd->disk.state & (1<component_size + after)/2); } err = sysfs_set_num(sra, sd, "new_offset", new_data_offset); } if (err < 0) { if (errno == E2BIG && data_offset != INVALID_SECTORS) { pr_err("data-offset is too big for %s\n", dn); goto release; } if (sd == sra->devs && (errno == ENOENT || errno == E2BIG)) /* Early kernel, no 'new_offset' file, * or kernel doesn't like us. * For RAID5/6 this is not fatal */ return 1; pr_err("Cannot set new_offset for %s\n", dn); break; } } return err; release: return -1; fallback: /* Just use a backup file */ return 1; } static int raid10_reshape(char *container, int fd, char *devname, struct supertype *st, struct mdinfo *info, struct reshape *reshape, unsigned long long data_offset, int force, int verbose) { /* Changing raid_disks, layout, chunksize or possibly * just data_offset for a RAID10. * We must always change data_offset. We change by at least * ->min_offset_change which is the largest of the old and new * chunk sizes. * If raid_disks is increasing, then data_offset must decrease * by at least this copy size. * If raid_disks is unchanged, data_offset must increase or * decrease by at least min_offset_change but preferably by much more. * We choose half of the available space. * If raid_disks is decreasing, data_offset must increase by * at least min_offset_change. To allow of this, component_size * must be decreased by the same amount. * * So we calculate the required minimum and direction, possibly * reduce the component_size, then iterate through the devices * and set the new_data_offset. * If that all works, we set chunk_size, layout, raid_disks, and start * 'reshape' */ struct mdinfo *sra; unsigned long long min; int err = 0; sra = sysfs_read(fd, NULL, GET_COMPONENT|GET_DEVS|GET_OFFSET|GET_STATE|GET_CHUNK ); if (!sra) { pr_err("%s: Cannot get array details from sysfs\n", devname); goto release; } min = reshape->min_offset_change; if (info->delta_disks) sysfs_set_str(sra, NULL, "reshape_direction", info->delta_disks < 0 ? "backwards" : "forwards"); if (info->delta_disks < 0 && info->space_after < min) { int rv = sysfs_set_num(sra, NULL, "component_size", (sra->component_size - min)/2); if (rv) { pr_err("cannot reduce component size\n"); goto release; } } err = set_new_data_offset(sra, st, devname, info->delta_disks, data_offset, min, 0); if (err == 1) { pr_err("Cannot set new_data_offset: RAID10 reshape not\n"); cont_err("supported on this kernel\n"); err = -1; } if (err < 0) goto release; if (!err && sysfs_set_num(sra, NULL, "chunk_size", info->new_chunk) < 0) err = errno; if (!err && sysfs_set_num(sra, NULL, "layout", reshape->after.layout) < 0) err = errno; if (!err && sysfs_set_num(sra, NULL, "raid_disks", info->array.raid_disks + info->delta_disks) < 0) err = errno; if (!err && sysfs_set_str(sra, NULL, "sync_action", "reshape") < 0) err = errno; if (err) { pr_err("Cannot set array shape for %s\n", devname); if (err == EBUSY && (info->array.state & (1<devs; sd; sd = sd->next) { char *dn; int dfd; struct supertype *st2; struct mdinfo info2; if (sd->disk.state & (1<disk.major, sd->disk.minor, 0); dfd = dev_open(dn, O_RDONLY); if (dfd < 0) break; st2 = dup_super(st); if (st2->ss->load_super(st2,dfd, NULL)) { close(dfd); free(st2); break; } close(dfd); st2->ss->getinfo_super(st2, &info2, NULL); st2->ss->free_super(st2); free(st2); if (first || min_space_before > info2.space_before) min_space_before = info2.space_before; if (first || min_space_after > info2.space_after) min_space_after = info2.space_after; first = 0; } if (sd == NULL && !first) { info->space_after = min_space_after; info->space_before = min_space_before; } sysfs_free(sra); } static void update_cache_size(char *container, struct mdinfo *sra, struct mdinfo *info, int disks, unsigned long long blocks) { /* Check that the internal stripe cache is * large enough, or it won't work. * It must hold at least 4 stripes of the larger * chunk size */ unsigned long cache; cache = max(info->array.chunk_size, info->new_chunk); cache *= 4; /* 4 stripes minimum */ cache /= 512; /* convert to sectors */ /* make sure there is room for 'blocks' with a bit to spare */ if (cache < 16 + blocks / disks) cache = 16 + blocks / disks; cache /= (4096/512); /* Convert from sectors to pages */ if (sra->cache_size < cache) subarray_set_num(container, sra, "stripe_cache_size", cache+1); } static int impose_reshape(struct mdinfo *sra, struct mdinfo *info, struct supertype *st, int fd, int restart, char *devname, char *container, struct reshape *reshape) { struct mdu_array_info_s array; sra->new_chunk = info->new_chunk; if (restart) { /* for external metadata checkpoint saved by mdmon can be lost * or missed /due to e.g. crash/. Check if md is not during * restart farther than metadata points to. * If so, this means metadata information is obsolete. */ if (st->ss->external) verify_reshape_position(info, reshape->level); sra->reshape_progress = info->reshape_progress; } else { sra->reshape_progress = 0; if (reshape->after.data_disks < reshape->before.data_disks) /* start from the end of the new array */ sra->reshape_progress = (sra->component_size * reshape->after.data_disks); } md_get_array_info(fd, &array); if (info->array.chunk_size == info->new_chunk && reshape->before.layout == reshape->after.layout && st->ss->external == 0) { /* use SET_ARRAY_INFO but only if reshape hasn't started */ array.raid_disks = reshape->after.data_disks + reshape->parity; if (!restart && md_set_array_info(fd, &array) != 0) { int err = errno; pr_err("Cannot set device shape for %s: %s\n", devname, strerror(errno)); if (err == EBUSY && (array.state & (1<new_chunk) < 0) err = errno; if (!err && sysfs_set_num(sra, NULL, "layout", reshape->after.layout) < 0) err = errno; /* new_level is introduced in kernel 6.12 */ if (!err && get_linux_version() >= 6012000 && sysfs_set_num(sra, NULL, "new_level", info->new_level) < 0) err = errno; if (!err && subarray_set_num(container, sra, "raid_disks", reshape->after.data_disks + reshape->parity) < 0) err = errno; if (err) { pr_err("Cannot set device shape for %s\n", devname); if (err == EBUSY && (array.state & (1<= 0) pr_err("level of %s changed to %s\n", devname, c); } return 0; } int sigterm = 0; static void catch_term(int sig) { sigterm = 1; } static int reshape_array(char *container, int fd, char *devname, struct supertype *st, struct mdinfo *info, int force, struct mddev_dev *devlist, unsigned long long data_offset, char *backup_file, int verbose, int forked, int restart, int freeze_reshape) { struct reshape reshape; int spares_needed; char *msg; int orig_level = UnSet; int odisks; int delayed; struct mdu_array_info_s array; char *c; struct mddev_dev *dv; int added_disks; int *fdlist = NULL; unsigned long long *offsets = NULL; int d; int nrdisks; int err; unsigned long blocks; unsigned long long array_size; int done; struct mdinfo *sra = NULL; char buf[SYSFS_MAX_BUF_SIZE]; bool located_backup = false; /* when reshaping a RAID0, the component_size might be zero. * So try to fix that up. */ if (md_get_array_info(fd, &array) != 0) { dprintf("Cannot get array information.\n"); goto release; } if (st->update_tail == NULL) st->update_tail = &st->updates; if (array.level == 0 && info->component_size == 0) { get_dev_size(fd, NULL, &array_size); info->component_size = array_size / array.raid_disks; } if (array.level == 10) /* Need space_after info */ get_space_after(fd, st, info); if (info->reshape_active) { int new_level = info->new_level; info->new_level = UnSet; if (info->delta_disks > 0) info->array.raid_disks -= info->delta_disks; msg = analyse_change(devname, info, &reshape); info->new_level = new_level; if (info->delta_disks > 0) info->array.raid_disks += info->delta_disks; if (!restart) /* Make sure the array isn't read-only */ ioctl(fd, RESTART_ARRAY_RW, 0); } else msg = analyse_change(devname, info, &reshape); if (msg) { /* if msg == "", error has already been printed */ if (msg[0]) pr_err("%s\n", msg); goto release; } if (restart && (reshape.level != info->array.level || reshape.before.layout != info->array.layout || reshape.before.data_disks + reshape.parity != info->array.raid_disks - max(0, info->delta_disks))) { pr_err("reshape info is not in native format - cannot continue.\n"); goto release; } if (st->ss->external && restart && (info->reshape_progress == 0) && !((sysfs_get_str(info, NULL, "sync_action", buf, sizeof(buf)) > 0) && (strncmp(buf, "reshape", 7) == 0))) { /* When reshape is restarted from '0', very begin of array * it is possible that for external metadata reshape and array * configuration doesn't happen. * Check if md has the same opinion, and reshape is restarted * from 0. If so, this is regular reshape start after reshape * switch in metadata to next array only. */ if ((verify_reshape_position(info, reshape.level) >= 0) && (info->reshape_progress == 0)) restart = 0; } if (restart) { /* * reshape already started. just skip to monitoring * the reshape */ if (reshape.backup_blocks == 0) return 0; if (restart & RESHAPE_NO_BACKUP) return 0; /* Need 'sra' down at 'started:' */ sra = sysfs_read(fd, NULL, GET_COMPONENT|GET_DEVS|GET_OFFSET|GET_STATE| GET_CHUNK|GET_CACHE); if (!sra) { pr_err("%s: Cannot get array details from sysfs\n", devname); goto release; } if (!backup_file) { backup_file = locate_backup(sra->sys_name); located_backup = true; } goto started; } /* The container is frozen but the array may not be. * So freeze the array so spares don't get put to the wrong use * FIXME there should probably be a cleaner separation between * freeze_array and freeze_container. */ sysfs_freeze_array(info); /* Check we have enough spares to not be degraded */ added_disks = 0; for (dv = devlist; dv ; dv=dv->next) added_disks++; spares_needed = max(reshape.before.data_disks, reshape.after.data_disks) + reshape.parity - array.raid_disks; if (!force && info->new_level > 1 && info->array.level > 1 && spares_needed > info->array.spare_disks + added_disks) { pr_err("Need %d spare%s to avoid degraded array, and only have %d.\n" " Use --force to over-ride this check.\n", spares_needed, spares_needed == 1 ? "" : "s", info->array.spare_disks + added_disks); goto release; } /* Check we have enough spares to not fail */ spares_needed = max(reshape.before.data_disks, reshape.after.data_disks) - array.raid_disks; if ((info->new_level > 1 || info->new_level == 0) && spares_needed > info->array.spare_disks +added_disks) { pr_err("Need %d spare%s to create working array, and only have %d.\n", spares_needed, spares_needed == 1 ? "" : "s", info->array.spare_disks + added_disks); goto release; } if (reshape.level != array.level) { int err = impose_level(fd, reshape.level, devname, verbose); if (err) goto release; info->new_layout = UnSet; /* after level change, * layout is meaningless */ orig_level = array.level; sysfs_freeze_array(info); if (reshape.level > 0 && st->ss->external) { /* make sure mdmon is aware of the new level */ if (mdmon_running(container)) flush_mdmon(container); if (!mdmon_running(container)) start_mdmon(container); ping_monitor(container); if (wait_for_mdmon(container) == MDADM_STATUS_SUCCESS && !st->update_tail) st->update_tail = &st->updates; } } /* ->reshape_super might have chosen some spares from the * container that it wants to be part of the new array. * We can collect them with ->container_content and give * them to the kernel. */ if (st->ss->reshape_super && st->ss->container_content) { char *subarray = strchr(info->text_version+1, '/')+1; struct mdinfo *info2 = st->ss->container_content(st, subarray); struct mdinfo *d; if (info2) { if (sysfs_init(info2, fd, st->devnm)) { pr_err("unable to initialize sysfs for %s\n", st->devnm); free(info2); goto release; } /* When increasing number of devices, we need to set * new raid_disks before adding these, or they might * be rejected. */ if (reshape.backup_blocks && reshape.after.data_disks > reshape.before.data_disks) subarray_set_num(container, info2, "raid_disks", reshape.after.data_disks + reshape.parity); for (d = info2->devs; d; d = d->next) { if (d->disk.state == 0 && d->disk.raid_disk >= 0) { /* This is a spare that wants to * be part of the array. */ if (add_disk(fd, st, info2, d) < 0) { pr_err("Can not add disk %s\n", d->sys_name); free(info2); goto release; } } } sysfs_free(info2); } } /* We might have been given some devices to add to the * array. Now that the array has been changed to the right * level and frozen, we can safely add them. */ if (devlist) { if (Manage_subdevs(devname, fd, devlist, verbose, 0, UOPT_UNDEFINED, 0)) goto release; } if (reshape.backup_blocks == 0 && data_offset != INVALID_SECTORS) reshape.backup_blocks = reshape.before.data_disks * info->array.chunk_size/512; if (reshape.backup_blocks == 0) { /* No restriping needed, but we might need to impose * some more changes: layout, raid_disks, chunk_size */ /* read current array info */ if (md_get_array_info(fd, &array) != 0) { dprintf("Cannot get array information.\n"); goto release; } /* compare current array info with new values and if * it is different update them to new */ if (info->new_layout != UnSet && info->new_layout != array.layout) { array.layout = info->new_layout; if (md_set_array_info(fd, &array) != 0) { pr_err("failed to set new layout\n"); goto release; } else if (verbose >= 0) printf("layout for %s set to %d\n", devname, array.layout); } if (info->delta_disks != UnSet && info->delta_disks != 0 && array.raid_disks != (info->array.raid_disks + info->delta_disks)) { array.raid_disks += info->delta_disks; if (md_set_array_info(fd, &array) != 0) { pr_err("failed to set raid disks\n"); goto release; } else if (verbose >= 0) { printf("raid_disks for %s set to %d\n", devname, array.raid_disks); } } if (info->new_chunk != 0 && info->new_chunk != array.chunk_size) { if (sysfs_set_num(info, NULL, "chunk_size", info->new_chunk) != 0) { pr_err("failed to set chunk size\n"); goto release; } else if (verbose >= 0) printf("chunk size for %s set to %d\n", devname, info->new_chunk); } unfreeze(st); return 0; } /* * There are three possibilities. * 1/ The array will shrink. * We need to ensure the reshape will pause before reaching * the 'critical section'. We also need to fork and wait for * that to happen. When it does we * suspend/backup/complete/unfreeze * * 2/ The array will not change size. * This requires that we keep a backup of a sliding window * so that we can restore data after a crash. So we need * to fork and monitor progress. * In future we will allow the data_offset to change, so * a sliding backup becomes unnecessary. * * 3/ The array will grow. This is relatively easy. * However the kernel's restripe routines will cheerfully * overwrite some early data before it is safe. So we * need to make a backup of the early parts of the array * and be ready to restore it if rebuild aborts very early. * For externally managed metadata, we still need a forked * child to monitor the reshape and suspend IO over the region * that is being reshaped. * * We backup data by writing it to one spare, or to a * file which was given on command line. * * In each case, we first make sure that storage is available * for the required backup. * Then we: * - request the shape change. * - fork to handle backup etc. */ /* Check that we can hold all the data */ get_dev_size(fd, NULL, &array_size); if (reshape.new_size < (array_size/512)) { pr_err("this change will reduce the size of the array.\n" " use --grow --array-size first to truncate array.\n" " e.g. mdadm --grow %s --array-size %llu\n", devname, reshape.new_size/2); goto release; } if (array.level == 10) { /* Reshaping RAID10 does not require any data backup by * user-space. Instead it requires that the data_offset * is changed to avoid the need for backup. * So this is handled very separately */ if (restart) /* Nothing to do. */ return 0; return raid10_reshape(container, fd, devname, st, info, &reshape, data_offset, force, verbose); } sra = sysfs_read(fd, NULL, GET_COMPONENT|GET_DEVS|GET_OFFSET|GET_STATE|GET_CHUNK| GET_CACHE); if (!sra) { pr_err("%s: Cannot get array details from sysfs\n", devname); goto release; } if (!backup_file) switch(set_new_data_offset(sra, st, devname, reshape.after.data_disks - reshape.before.data_disks, data_offset, reshape.min_offset_change, 1)) { case -1: goto release; case 0: /* Updated data_offset, so it's easy now */ update_cache_size(container, sra, info, min(reshape.before.data_disks, reshape.after.data_disks), reshape.backup_blocks); /* Right, everything seems fine. Let's kick things off. */ sync_metadata(st); if (impose_reshape(sra, info, st, fd, restart, devname, container, &reshape) < 0) goto release; if (sysfs_set_str(sra, NULL, "sync_action", "reshape") < 0) { struct mdinfo *sd; if (errno != EINVAL) { pr_err("Failed to initiate reshape!\n"); goto release; } /* revert data_offset and try the old way */ for (sd = sra->devs; sd; sd = sd->next) { sysfs_set_num(sra, sd, "new_offset", sd->data_offset); sysfs_set_str(sra, NULL, "reshape_direction", "forwards"); } break; } if (info->new_level == reshape.level) return 0; /* need to adjust level when reshape completes */ switch(fork()) { case -1: /* ignore error, but don't wait */ return 0; default: /* parent */ return 0; case 0: manage_fork_fds(0); map_fork(); break; } close(fd); wait_reshape(sra); fd = open_dev(sra->sys_name); if (fd >= 0) impose_level(fd, info->new_level, devname, verbose); return 0; case 1: /* Couldn't set data_offset, try the old way */ if (data_offset != INVALID_SECTORS) { pr_err("Cannot update data_offset on this array\n"); goto release; } break; } started: /* Decide how many blocks (sectors) for a reshape * unit. The number we have so far is just a minimum */ blocks = reshape.backup_blocks; if (reshape.before.data_disks == reshape.after.data_disks) { /* Make 'blocks' bigger for better throughput, but * not so big that we reject it below. * Try for 16 megabytes */ while (blocks * 32 < sra->component_size && blocks < 16*1024*2) blocks *= 2; } else pr_err("Need to backup %luK of critical section..\n", blocks/2); if (blocks >= sra->component_size/2) { pr_err("%s: Something wrong - reshape aborted\n", devname); goto release; } /* Now we need to open all these devices so we can read/write. */ nrdisks = max(reshape.before.data_disks, reshape.after.data_disks) + reshape.parity + sra->array.spare_disks; fdlist = xcalloc((1+nrdisks), sizeof(int)); offsets = xcalloc((1+nrdisks), sizeof(offsets[0])); odisks = reshape.before.data_disks + reshape.parity; d = reshape_prepare_fdlist(devname, sra, odisks, nrdisks, blocks, backup_file, fdlist, offsets); if (d < odisks) { goto release; } if ((st->ss->manage_reshape == NULL) || (st->ss->recover_backup == NULL)) { if (backup_file == NULL) { if (reshape.after.data_disks <= reshape.before.data_disks) { pr_err("%s: Cannot grow - need backup-file\n", devname); pr_err(" Please provide one with \"--backup=...\"\n"); goto release; } else if (d == odisks) { pr_err("%s: Cannot grow - need a spare or backup-file to backup critical section\n", devname); goto release; } } else { if (!reshape_open_backup_file(backup_file, fd, devname, (signed)blocks, fdlist+d, offsets+d, sra->sys_name, restart)) { goto release; } d++; } } update_cache_size(container, sra, info, min(reshape.before.data_disks, reshape.after.data_disks), blocks); /* Right, everything seems fine. Let's kick things off. * If only changing raid_disks, use ioctl, else use * sysfs. */ sync_metadata(st); if (impose_reshape(sra, info, st, fd, restart, devname, container, &reshape) < 0) goto release; err = start_reshape(sra, restart, reshape.before.data_disks, reshape.after.data_disks, st); if (err) { pr_err("Cannot %s reshape for %s\n", restart ? "continue" : "start", devname); goto release; } if (restart) sysfs_set_str(sra, NULL, "array_state", "active"); if (freeze_reshape) { free(fdlist); free(offsets); sysfs_free(sra); pr_err("Reshape has to be continued from location %llu when root filesystem has been mounted.\n", sra->reshape_progress); return 1; } if (!forked) if (continue_via_systemd(container ?: sra->sys_name, GROW_SERVICE, NULL)) { free(fdlist); free(offsets); sysfs_free(sra); return 0; } /* Now we just need to kick off the reshape and watch, while * handling backups of the data... * This is all done by a forked background process. */ switch(forked ? 0 : fork()) { case -1: pr_err("Cannot run child to monitor reshape: %s\n", strerror(errno)); abort_reshape(sra); goto release; default: free(fdlist); free(offsets); sysfs_free(sra); return 0; case 0: map_fork(); break; } /* Close unused file descriptor in the forked process */ close_fd(&fd); /* If another array on the same devices is busy, the * reshape will wait for them. This would mean that * the first section that we suspend will stay suspended * for a long time. So check on that possibility * by looking for "DELAYED" in /proc/mdstat, and if found, * wait a while */ do { struct mdstat_ent *mds, *m; delayed = 0; mds = mdstat_read(1, 0); for (m = mds; m; m = m->next) if (strcmp(m->devnm, sra->sys_name) == 0) { if (m->resync && m->percent == RESYNC_DELAYED) delayed = 1; if (m->resync == 0) /* Haven't started the reshape thread * yet, wait a bit */ delayed = 2; break; } free_mdstat(mds); if (delayed == 1 && get_linux_version() < 3007000) { pr_err("Reshape is delayed, but cannot wait carefully with this kernel.\n" " You might experience problems until other reshapes complete.\n"); delayed = 0; } if (delayed) mdstat_wait(30 - (delayed-1) * 25); } while (delayed); mdstat_close(); mlockall(MCL_FUTURE); if (signal_s(SIGTERM, catch_term) == SIG_ERR) goto release; if (check_env("MDADM_GROW_VERIFY")) fd = open(devname, O_RDONLY | O_DIRECT); if (st->ss->external) { /* metadata handler takes it from here */ done = st->ss->manage_reshape( fd, sra, &reshape, st, blocks, fdlist, offsets, d - odisks, fdlist + odisks, offsets + odisks); } else done = child_monitor( fd, sra, &reshape, st, blocks, fdlist, offsets, d - odisks, fdlist + odisks, offsets + odisks); close_fd(&fd); free(fdlist); free(offsets); if (backup_file && done) { char *bul; bul = make_backup(sra->sys_name); if (bul) { char buf[1024]; int l = readlink(bul, buf, sizeof(buf) - 1); if (l > 0) { buf[l]=0; unlink(buf); } unlink(bul); free(bul); } unlink(backup_file); } if (!done) { abort_reshape(sra); goto out; } if (!st->ss->external && !(reshape.before.data_disks != reshape.after.data_disks && info->custom_array_size) && info->new_level == reshape.level && !forked) { /* no need to wait for the reshape to finish as * there is nothing more to do. */ sysfs_free(sra); exit(0); } wait_reshape(sra); if (st->ss->external) { /* Re-load the metadata as much could have changed */ int cfd = open_dev(st->container_devnm); if (cfd >= 0) { flush_mdmon(container); st->ss->free_super(st); st->ss->load_container(st, cfd, container); close(cfd); } } /* set new array size if required customer_array_size is used * by this metadata. */ if (reshape.before.data_disks != reshape.after.data_disks && info->custom_array_size) set_array_size(st, info, info->text_version); if (info->new_level != reshape.level) { fd = open_dev(sra->sys_name); if (fd < 0) { pr_err("Can't open %s\n", sra->sys_name); goto out; } impose_level(fd, info->new_level, sra->sys_name, verbose); close(fd); if (info->new_level == 0) st->update_tail = NULL; } out: sysfs_free(sra); if (forked) return 0; unfreeze(st); exit(0); release: if (located_backup) free(backup_file); free(fdlist); free(offsets); if (orig_level != UnSet && sra) { c = map_num(pers, orig_level); if (c && sysfs_set_str(sra, NULL, "level", c) == 0) pr_err("aborting level change\n"); } sysfs_free(sra); if (!forked) unfreeze(st); return 1; } /* mdfd handle is passed to be closed in child process (after fork). */ int reshape_container(char *container, char *devname, int mdfd, struct supertype *st, struct mdinfo *info, struct context *c, int forked, int restart) { struct mdinfo *cc = NULL; int rv = restart; char last_devnm[32] = ""; /* component_size is not meaningful for a container */ if (!restart && reshape_super_non_size(st, devname, info, c)) { unfreeze(st); return 1; } sync_metadata(st); /* ping monitor to be sure that update is on disk */ ping_monitor(container); if (!forked && !c->freeze_reshape) if (continue_via_systemd(container, GROW_SERVICE, NULL)) return 0; switch (forked ? 0 : fork()) { case -1: /* error */ perror("Cannot fork to complete reshape\n"); unfreeze(st); return 1; default: /* parent */ if (!c->freeze_reshape) printf("%s: multi-array reshape continues in background\n", Name); return 0; case 0: /* child */ manage_fork_fds(0); map_fork(); break; } /* close unused handle in child process */ if (mdfd > -1) close(mdfd); while(1) { /* For each member array with reshape_active, * we need to perform the reshape. * We pick the first array that needs reshaping and * reshape it. reshape_array() will re-read the metadata * so the next time through a different array should be * ready for reshape. * It is possible that the 'different' array will not * be assembled yet. In that case we simple exit. * When it is assembled, the mdadm which assembles it * will take over the reshape. */ struct mdinfo *content; int fd; struct mdstat_ent *mdstat; char *adev; dev_t devid; sysfs_free(cc); cc = st->ss->container_content(st, NULL); for (content = cc; content ; content = content->next) { char *subarray; if (!content->reshape_active) continue; subarray = strchr(content->text_version+1, '/')+1; mdstat = mdstat_by_subdev(subarray, container); if (!mdstat) continue; if (mdstat->active == 0) { pr_err("Skipping inactive array %s.\n", mdstat->devnm); free_mdstat(mdstat); mdstat = NULL; continue; } break; } if (!content) break; devid = devnm2devid(mdstat->devnm); adev = map_dev(major(devid), minor(devid), 0); if (!adev) adev = content->text_version; fd = open_dev(mdstat->devnm); if (fd < 0) { pr_err("Device %s cannot be opened for reshape.\n", adev); break; } if (strcmp(last_devnm, mdstat->devnm) == 0) { /* Do not allow for multiple reshape_array() calls for * the same array. * It can happen when reshape_array() returns without * error, when reshape is not finished (wrong reshape * starting/continuation conditions). Mdmon doesn't * switch to next array in container and reentry * conditions for the same array occur. * This is possibly interim until the behaviour of * reshape_array is resolved(). */ printf("%s: Multiple reshape execution detected for device %s.\n", Name, adev); close(fd); break; } strcpy(last_devnm, mdstat->devnm); if (sysfs_init(content, fd, mdstat->devnm)) { pr_err("Unable to initialize sysfs for %s\n", mdstat->devnm); rv = 1; close_fd(&fd); break; } if (mdmon_running(container)) flush_mdmon(container); rv = reshape_array(container, fd, adev, st, content, c->force, NULL, INVALID_SECTORS, c->backup_file, c->verbose, 1, restart, c->freeze_reshape); close(fd); if (c->freeze_reshape) { sysfs_free(cc); exit(0); } restart = 0; if (rv) break; if (mdmon_running(container)) flush_mdmon(container); } if (!rv) unfreeze(st); sysfs_free(cc); exit(0); } /* * We run a child process in the background which performs the following * steps: * - wait for resync to reach a certain point * - suspend io to the following section * - backup that section * - allow resync to proceed further * - resume io * - discard the backup. * * When are combined in slightly different ways in the three cases. * Grow: * - suspend/backup/allow/wait/resume/discard * Shrink: * - allow/wait/suspend/backup/allow/wait/resume/discard * same-size: * - wait/resume/discard/suspend/backup/allow * * suspend/backup/allow always come together * wait/resume/discard do too. * For the same-size case we have two backups to improve flow. * */ int progress_reshape(struct mdinfo *info, struct reshape *reshape, unsigned long long backup_point, unsigned long long wait_point, unsigned long long *suspend_point, unsigned long long *reshape_completed, int *frozen) { /* This function is called repeatedly by the reshape manager. * It determines how much progress can safely be made and allows * that progress. * - 'info' identifies the array and particularly records in * ->reshape_progress the metadata's knowledge of progress * This is a sector offset from the start of the array * of the next array block to be relocated. This number * may increase from 0 or decrease from array_size, depending * on the type of reshape that is happening. * Note that in contrast, 'sync_completed' is a block count of the * reshape so far. It gives the distance between the start point * (head or tail of device) and the next place that data will be * written. It always increases. * - 'reshape' is the structure created by analyse_change * - 'backup_point' shows how much the metadata manager has backed-up * data. For reshapes with increasing progress, it is the next address * to be backed up, previous addresses have been backed-up. For * decreasing progress, it is the earliest address that has been * backed up - later address are also backed up. * So addresses between reshape_progress and backup_point are * backed up providing those are in the 'correct' order. * - 'wait_point' is an array address. When reshape_completed * passes this point, progress_reshape should return. It might * return earlier if it determines that ->reshape_progress needs * to be updated or further backup is needed. * - suspend_point is maintained by progress_reshape and the caller * should not touch it except to initialise to zero. * It is an array address and it only increases in 2.6.37 and earlier. * This makes it difficult to handle reducing reshapes with * external metadata. * However: it is similar to backup_point in that it records the * other end of a suspended region from reshape_progress. * it is moved to extend the region that is safe to backup and/or * reshape * - reshape_completed is read from sysfs and returned. The caller * should copy this into ->reshape_progress when it has reason to * believe that the metadata knows this, and any backup outside this * has been erased. * * Return value is: * 1 if more data from backup_point - but only as far as suspend_point, * should be backed up * 0 if things are progressing smoothly * -1 if the reshape is finished because it is all done, * -2 if the reshape is finished due to an error. */ int advancing = (reshape->after.data_disks >= reshape->before.data_disks); unsigned long long need_backup; /* All data between start of array and * here will at some point need to * be backed up. */ unsigned long long read_offset, write_offset; unsigned long long write_range; unsigned long long max_progress, target, completed; unsigned long long array_size = (info->component_size * reshape->before.data_disks); int fd; char buf[SYSFS_MAX_BUF_SIZE]; /* First, we unsuspend any region that is now known to be safe. * If suspend_point is on the 'wrong' side of reshape_progress, then * we don't have or need suspension at the moment. This is true for * native metadata when we don't need to back-up. */ if (advancing) { if (info->reshape_progress <= *suspend_point) sysfs_set_num(info, NULL, "suspend_lo", info->reshape_progress); } else { /* Note: this won't work in 2.6.37 and before. * Something somewhere should make sure we don't need it! */ if (info->reshape_progress >= *suspend_point) sysfs_set_num(info, NULL, "suspend_hi", info->reshape_progress); } /* Now work out how far it is safe to progress. * If the read_offset for ->reshape_progress is less than * 'blocks' beyond the write_offset, we can only progress as far * as a backup. * Otherwise we can progress until the write_offset for the new location * reaches (within 'blocks' of) the read_offset at the current location. * However that region must be suspended unless we are using native * metadata. * If we need to suspend more, we limit it to 128M per device, which is * rather arbitrary and should be some time-based calculation. */ read_offset = info->reshape_progress / reshape->before.data_disks; write_offset = info->reshape_progress / reshape->after.data_disks; write_range = info->new_chunk/512; if (reshape->before.data_disks == reshape->after.data_disks) need_backup = array_size; else need_backup = reshape->backup_blocks; if (advancing) { if (read_offset < write_offset + write_range) max_progress = backup_point; else max_progress = read_offset * reshape->after.data_disks; } else { if (read_offset > write_offset - write_range) /* Can only progress as far as has been backed up, * which must be suspended */ max_progress = backup_point; else if (info->reshape_progress <= need_backup) max_progress = backup_point; else { if (info->array.major_version >= 0) /* Can progress until backup is needed */ max_progress = need_backup; else { /* Can progress until metadata update is required */ max_progress = read_offset * reshape->after.data_disks; /* but data must be suspended */ if (max_progress < *suspend_point) max_progress = *suspend_point; } } } /* We know it is safe to progress to 'max_progress' providing * it is suspended or we are using native metadata. * Consider extending suspend_point 128M per device if it * is less than 64M per device beyond reshape_progress. * But always do a multiple of 'blocks' * FIXME this is too big - it takes to long to complete * this much. */ target = 64*1024*2 * min(reshape->before.data_disks, reshape->after.data_disks); target /= reshape->backup_blocks; if (target < 2) target = 2; target *= reshape->backup_blocks; /* For externally managed metadata we always need to suspend IO to * the area being reshaped so we regularly push suspend_point forward. * For native metadata we only need the suspend if we are going to do * a backup. */ if (advancing) { if ((need_backup > info->reshape_progress || info->array.major_version < 0) && *suspend_point < info->reshape_progress + target) { if (need_backup < *suspend_point + 2 * target) *suspend_point = need_backup; else if (*suspend_point + 2 * target < array_size) *suspend_point += 2 * target; else *suspend_point = array_size; sysfs_set_num(info, NULL, "suspend_hi", *suspend_point); if (max_progress > *suspend_point) max_progress = *suspend_point; } } else { if (info->array.major_version >= 0) { /* Only need to suspend when about to backup */ if (info->reshape_progress < need_backup * 2 && *suspend_point > 0) { *suspend_point = 0; sysfs_set_num(info, NULL, "suspend_lo", 0); sysfs_set_num(info, NULL, "suspend_hi", need_backup); } } else { /* Need to suspend continually */ if (info->reshape_progress < *suspend_point) *suspend_point = info->reshape_progress; if (*suspend_point + target < info->reshape_progress) /* No need to move suspend region yet */; else { if (*suspend_point >= 2 * target) *suspend_point -= 2 * target; else *suspend_point = 0; sysfs_set_num(info, NULL, "suspend_lo", *suspend_point); } if (max_progress < *suspend_point) max_progress = *suspend_point; } } /* now set sync_max to allow that progress. sync_max, like * sync_completed is a count of sectors written per device, so * we find the difference between max_progress and the start point, * and divide that by after.data_disks to get a sync_max * number. * At the same time we convert wait_point to a similar number * for comparing against sync_completed. */ /* scale down max_progress to per_disk */ max_progress /= reshape->after.data_disks; /* * Round to chunk size as some kernels give an erroneously * high number */ max_progress /= info->new_chunk/512; max_progress *= info->new_chunk/512; /* And round to old chunk size as the kernel wants that */ max_progress /= info->array.chunk_size/512; max_progress *= info->array.chunk_size/512; /* Limit progress to the whole device */ if (max_progress > info->component_size) max_progress = info->component_size; wait_point /= reshape->after.data_disks; if (!advancing) { /* switch from 'device offset' to 'processed block count' */ max_progress = info->component_size - max_progress; wait_point = info->component_size - wait_point; } if (!*frozen) sysfs_set_num(info, NULL, "sync_max", max_progress); /* Now wait. If we have already reached the point that we were * asked to wait to, don't wait at all, else wait for any change. * We need to select on 'sync_completed' as that is the place that * notifications happen, but we are really interested in * 'reshape_position' */ fd = sysfs_get_fd(info, NULL, "sync_completed"); if (fd < 0) goto check_progress; if (sysfs_fd_get_ll(fd, &completed) < 0) goto check_progress; while (completed < max_progress && completed < wait_point) { /* Check that sync_action is still 'reshape' to avoid * waiting forever on a dead array */ char action[SYSFS_MAX_BUF_SIZE]; if (sysfs_get_str(info, NULL, "sync_action", action, sizeof(action)) <= 0) break; /* Some kernels reset 'sync_completed' to zero * before setting 'sync_action' to 'idle'. * So we need these extra tests. */ if (completed == 0 && advancing && strncmp(action, "idle", 4) == 0 && info->reshape_progress > 0) { info->reshape_progress = need_backup; break; } if (completed == 0 && !advancing && strncmp(action, "idle", 4) == 0 && info->reshape_progress < (info->component_size * reshape->after.data_disks)) { info->reshape_progress = need_backup; break; } if (strncmp(action, "reshape", 7) != 0) break; sysfs_wait(fd, NULL); if (sysfs_fd_get_ll(fd, &completed) < 0) goto check_progress; } /* Some kernels reset 'sync_completed' to zero, * we need to have real point we are in md. * So in that case, read 'reshape_position' from sysfs. */ if (completed == 0) { unsigned long long reshapep; char action[SYSFS_MAX_BUF_SIZE]; if (sysfs_get_str(info, NULL, "sync_action", action, sizeof(action)) > 0 && strncmp(action, "idle", 4) == 0 && sysfs_get_ll(info, NULL, "reshape_position", &reshapep) == 0) *reshape_completed = reshapep; } else { /* some kernels can give an incorrectly high * 'completed' number, so round down */ completed /= (info->new_chunk/512); completed *= (info->new_chunk/512); /* Convert 'completed' back in to a 'progress' number */ completed *= reshape->after.data_disks; if (!advancing) completed = (info->component_size * reshape->after.data_disks - completed); *reshape_completed = completed; } close(fd); /* We return the need_backup flag. Caller will decide * how much - a multiple of ->backup_blocks up to *suspend_point */ if (advancing) return need_backup > info->reshape_progress; else return need_backup >= info->reshape_progress; check_progress: /* if we couldn't read a number from sync_completed, then * either the reshape did complete, or it aborted. * We can tell which by checking for 'none' in reshape_position. * If it did abort, then it might immediately restart if it * it was just a device failure that leaves us degraded but * functioning. */ if (sysfs_get_str(info, NULL, "reshape_position", buf, sizeof(buf)) < 0 || str_is_none(buf) == false) { /* The abort might only be temporary. Wait up to 10 * seconds for fd to contain a valid number again. */ int wait = 10000; int rv = -2; unsigned long long new_sync_max; while (fd >= 0 && rv < 0 && wait > 0) { if (sysfs_wait(fd, &wait) != 1) break; switch (sysfs_fd_get_ll(fd, &completed)) { case 0: /* all good again */ rv = 1; /* If "sync_max" is no longer max_progress * we need to freeze things */ sysfs_get_ll(info, NULL, "sync_max", &new_sync_max); *frozen = (new_sync_max != max_progress); break; case -2: /* read error - abort */ wait = 0; break; } } if (fd >= 0) close(fd); return rv; /* abort */ } else { /* Maybe racing with array shutdown - check state */ if (fd >= 0) close(fd); if (sysfs_get_str(info, NULL, "array_state", buf, sizeof(buf)) < 0 || strncmp(buf, "inactive", 8) == 0 || strncmp(buf, "clear",5) == 0) return -2; /* abort */ return -1; /* complete */ } } /* FIXME return status is never checked */ static int grow_backup(struct mdinfo *sra, unsigned long long offset, /* per device */ unsigned long stripes, /* per device, in old chunks */ int *sources, unsigned long long *offsets, int disks, int chunk, int level, int layout, int dests, int *destfd, unsigned long long *destoffsets, int part, int *degraded, char *buf) { /* Backup 'blocks' sectors at 'offset' on each device of the array, * to storage 'destfd' (offset 'destoffsets'), after first * suspending IO. Then allow resync to continue * over the suspended section. * Use part 'part' of the backup-super-block. */ int odata = disks; int rv = 0; int i; unsigned long long ll; int new_degraded; //printf("offset %llu\n", offset); if (level >= 4) odata--; if (level == 6) odata--; /* Check that array hasn't become degraded, else we might backup the wrong data */ if (sysfs_get_ll(sra, NULL, "degraded", &ll) < 0) return -1; /* FIXME this error is ignored */ new_degraded = (int)ll; if (new_degraded != *degraded) { /* check each device to ensure it is still working */ struct mdinfo *sd; for (sd = sra->devs ; sd ; sd = sd->next) { if (sd->disk.state & (1<disk.state & (1<disk.state = (1<disk.raid_disk >= 0 && sources[sd->disk.raid_disk] >= 0) { close(sources[sd->disk.raid_disk]); sources[sd->disk.raid_disk] = -1; } } } } *degraded = new_degraded; } if (part) { bsb.arraystart2 = __cpu_to_le64(offset * odata); bsb.length2 = __cpu_to_le64(stripes * (chunk/512) * odata); } else { bsb.arraystart = __cpu_to_le64(offset * odata); bsb.length = __cpu_to_le64(stripes * (chunk/512) * odata); } if (part) bsb.magic[15] = '2'; for (i = 0; i < dests; i++) if (part) lseek64(destfd[i], destoffsets[i] + __le64_to_cpu(bsb.devstart2)*512, 0); else lseek64(destfd[i], destoffsets[i], 0); rv = save_stripes(sources, offsets, disks, chunk, level, layout, dests, destfd, offset * 512 * odata, stripes * chunk * odata, buf); if (rv) return rv; bsb.mtime = __cpu_to_le64(time(0)); for (i = 0; i < dests; i++) { bsb.devstart = __cpu_to_le64(destoffsets[i]/512); bsb.sb_csum = bsb_csum((char*)&bsb, ((char*)&bsb.sb_csum)-((char*)&bsb)); if (memcmp(bsb.magic, "md_backup_data-2", 16) == 0) bsb.sb_csum2 = bsb_csum((char*)&bsb, ((char*)&bsb.sb_csum2)-((char*)&bsb)); rv = -1; if ((unsigned long long)lseek64(destfd[i], destoffsets[i] - 4096, 0) != destoffsets[i] - 4096) break; if (write(destfd[i], &bsb, 512) != 512) break; if (destoffsets[i] > 4096) { if ((unsigned long long)lseek64(destfd[i], destoffsets[i]+stripes*chunk*odata, 0) != destoffsets[i]+stripes*chunk*odata) break; if (write(destfd[i], &bsb, 512) != 512) break; } fsync(destfd[i]); rv = 0; } return rv; } /* in 2.6.30, the value reported by sync_completed can be * less that it should be by one stripe. * This only happens when reshape hits sync_max and pauses. * So allow wait_backup to either extent sync_max further * than strictly necessary, or return before the * sync has got quite as far as we would really like. * This is what 'blocks2' is for. * The various caller give appropriate values so that * every works. */ /* FIXME return value is often ignored */ static int forget_backup(int dests, int *destfd, unsigned long long *destoffsets, int part) { /* * Erase backup 'part' (which is 0 or 1) */ int i; int rv; if (part) { bsb.arraystart2 = __cpu_to_le64(0); bsb.length2 = __cpu_to_le64(0); } else { bsb.arraystart = __cpu_to_le64(0); bsb.length = __cpu_to_le64(0); } bsb.mtime = __cpu_to_le64(time(0)); rv = 0; for (i = 0; i < dests; i++) { bsb.devstart = __cpu_to_le64(destoffsets[i]/512); bsb.sb_csum = bsb_csum((char*)&bsb, ((char*)&bsb.sb_csum)-((char*)&bsb)); if (memcmp(bsb.magic, "md_backup_data-2", 16) == 0) bsb.sb_csum2 = bsb_csum((char*)&bsb, ((char*)&bsb.sb_csum2)-((char*)&bsb)); if ((unsigned long long)lseek64(destfd[i], destoffsets[i]-4096, 0) != destoffsets[i]-4096) rv = -1; if (rv == 0 && write(destfd[i], &bsb, 512) != 512) rv = -1; fsync(destfd[i]); } return rv; } static void fail(char *msg) { int rv; rv = (write(2, msg, strlen(msg)) != (int)strlen(msg)); rv |= (write(2, "\n", 1) != 1); exit(rv ? 1 : 2); } static char *abuf, *bbuf; static unsigned long long abuflen; static void validate(int afd, int bfd, unsigned long long offset) { /* check that the data in the backup against the array. * This is only used for regression testing and should not * be used while the array is active */ if (afd < 0) return; if (lseek64(bfd, offset - 4096, 0) < 0) { pr_err("lseek64 fails %d:%s\n", errno, strerror(errno)); return; } if (read(bfd, &bsb2, 512) != 512) fail("cannot read bsb"); if (bsb2.sb_csum != bsb_csum((char*)&bsb2, ((char*)&bsb2.sb_csum)-((char*)&bsb2))) fail("first csum bad"); if (memcmp(bsb2.magic, "md_backup_data", 14) != 0) fail("magic is bad"); if (memcmp(bsb2.magic, "md_backup_data-2", 16) == 0 && bsb2.sb_csum2 != bsb_csum((char*)&bsb2, ((char*)&bsb2.sb_csum2)-((char*)&bsb2))) fail("second csum bad"); if (__le64_to_cpu(bsb2.devstart)*512 != offset) fail("devstart is wrong"); if (bsb2.length) { unsigned long long len = __le64_to_cpu(bsb2.length)*512; if (abuflen < len) { free(abuf); free(bbuf); abuflen = len; if (posix_memalign((void**)&abuf, 4096, abuflen) || posix_memalign((void**)&bbuf, 4096, abuflen)) { abuflen = 0; /* just stop validating on mem-alloc failure */ return; } } if (lseek64(bfd, offset, 0) < 0) { pr_err("lseek64 fails %d:%s\n", errno, strerror(errno)); goto out; } if ((unsigned long long)read(bfd, bbuf, len) != len) { //printf("len %llu\n", len); fail("read first backup failed"); } if (lseek64(afd, __le64_to_cpu(bsb2.arraystart)*512, 0) < 0) { pr_err("lseek64 fails %d:%s\n", errno, strerror(errno)); goto out; } if ((unsigned long long)read(afd, abuf, len) != len) fail("read first from array failed"); if (memcmp(bbuf, abuf, len) != 0) fail("data1 compare failed"); } if (bsb2.length2) { unsigned long long len = __le64_to_cpu(bsb2.length2)*512; if (abuflen < len) { free(abuf); free(bbuf); abuflen = len; abuf = xmalloc(abuflen); bbuf = xmalloc(abuflen); } if (lseek64(bfd, offset+__le64_to_cpu(bsb2.devstart2)*512, 0) < 0) { pr_err("lseek64 fails %d:%s\n", errno, strerror(errno)); goto out; } if ((unsigned long long)read(bfd, bbuf, len) != len) fail("read second backup failed"); if (lseek64(afd, __le64_to_cpu(bsb2.arraystart2)*512, 0) < 0) { pr_err("lseek64 fails %d:%s\n", errno, strerror(errno)); goto out; } if ((unsigned long long)read(afd, abuf, len) != len) fail("read second from array failed"); if (memcmp(bbuf, abuf, len) != 0) fail("data2 compare failed"); } out: free(abuf); free(bbuf); return; } int child_monitor(int afd, struct mdinfo *sra, struct reshape *reshape, struct supertype *st, unsigned long blocks, int *fds, unsigned long long *offsets, int dests, int *destfd, unsigned long long *destoffsets) { /* Monitor a reshape where backup is being performed using * 'native' mechanism - either to a backup file, or * to some space in a spare. */ char *buf; int degraded = -1; unsigned long long suspend_point, array_size; unsigned long long backup_point, wait_point; unsigned long long reshape_completed; int done = 0; int increasing = reshape->after.data_disks >= reshape->before.data_disks; int part = 0; /* The next part of the backup area to fill. It * may already be full, so we need to check */ int level = reshape->level; int layout = reshape->before.layout; int data = reshape->before.data_disks; int disks = reshape->before.data_disks + reshape->parity; int chunk = sra->array.chunk_size; struct mdinfo *sd; unsigned long stripes; int uuid[4]; int frozen = 0; /* set up the backup-super-block. This requires the * uuid from the array. */ /* Find a superblock */ for (sd = sra->devs; sd; sd = sd->next) { char *dn; int devfd; int ok; if (sd->disk.state & (1<disk.major, sd->disk.minor, 1); devfd = dev_open(dn, O_RDONLY); if (devfd < 0) continue; ok = st->ss->load_super(st, devfd, NULL); close(devfd); if (ok == 0) break; } if (!sd) { pr_err("Cannot find a superblock\n"); return 0; } memset(&bsb, 0, 512); memcpy(bsb.magic, "md_backup_data-1", 16); st->ss->uuid_from_super(st, uuid); memcpy(bsb.set_uuid, uuid, 16); bsb.mtime = __cpu_to_le64(time(0)); bsb.devstart2 = blocks; stripes = blocks / (sra->array.chunk_size/512) / reshape->before.data_disks; if (posix_memalign((void**)&buf, 4096, disks * chunk)) /* Don't start the 'reshape' */ return 0; if (increasing) { array_size = sra->component_size * reshape->after.data_disks; backup_point = sra->reshape_progress; suspend_point = 0; } else { array_size = sra->component_size * reshape->before.data_disks; backup_point = reshape->backup_blocks; suspend_point = array_size; } while (!done) { int rv; /* Want to return as soon the oldest backup slot can * be released as that allows us to start backing up * some more, providing suspend_point has been * advanced, which it should have. */ if (increasing) { wait_point = array_size; if (part == 0 && __le64_to_cpu(bsb.length) > 0) wait_point = (__le64_to_cpu(bsb.arraystart) + __le64_to_cpu(bsb.length)); if (part == 1 && __le64_to_cpu(bsb.length2) > 0) wait_point = (__le64_to_cpu(bsb.arraystart2) + __le64_to_cpu(bsb.length2)); } else { wait_point = 0; if (part == 0 && __le64_to_cpu(bsb.length) > 0) wait_point = __le64_to_cpu(bsb.arraystart); if (part == 1 && __le64_to_cpu(bsb.length2) > 0) wait_point = __le64_to_cpu(bsb.arraystart2); } reshape_completed = sra->reshape_progress; rv = progress_reshape(sra, reshape, backup_point, wait_point, &suspend_point, &reshape_completed, &frozen); /* external metadata would need to ping_monitor here */ sra->reshape_progress = reshape_completed; /* Clear any backup region that is before 'here' */ if (increasing) { if (__le64_to_cpu(bsb.length) > 0 && reshape_completed >= (__le64_to_cpu(bsb.arraystart) + __le64_to_cpu(bsb.length))) forget_backup(dests, destfd, destoffsets, 0); if (__le64_to_cpu(bsb.length2) > 0 && reshape_completed >= (__le64_to_cpu(bsb.arraystart2) + __le64_to_cpu(bsb.length2))) forget_backup(dests, destfd, destoffsets, 1); } else { if (__le64_to_cpu(bsb.length) > 0 && reshape_completed <= (__le64_to_cpu(bsb.arraystart))) forget_backup(dests, destfd, destoffsets, 0); if (__le64_to_cpu(bsb.length2) > 0 && reshape_completed <= (__le64_to_cpu(bsb.arraystart2))) forget_backup(dests, destfd, destoffsets, 1); } if (sigterm) rv = -2; if (rv < 0) { if (rv == -1) done = 1; break; } if (rv == 0 && increasing && !st->ss->external) { /* No longer need to monitor this reshape */ sysfs_set_str(sra, NULL, "sync_max", "max"); done = 1; break; } while (rv) { unsigned long long offset; unsigned long actual_stripes; /* Need to backup some data. * If 'part' is not used and the desired * backup size is suspended, do a backup, * then consider the next part. */ /* Check that 'part' is unused */ if (part == 0 && __le64_to_cpu(bsb.length) != 0) break; if (part == 1 && __le64_to_cpu(bsb.length2) != 0) break; offset = backup_point / data; actual_stripes = stripes; if (increasing) { if (offset + actual_stripes * (chunk/512) > sra->component_size) actual_stripes = ((sra->component_size - offset) / (chunk/512)); if (offset + actual_stripes * (chunk/512) > suspend_point/data) break; } else { if (offset < actual_stripes * (chunk/512)) actual_stripes = offset / (chunk/512); offset -= actual_stripes * (chunk/512); if (offset < suspend_point/data) break; } if (actual_stripes == 0) break; grow_backup(sra, offset, actual_stripes, fds, offsets, disks, chunk, level, layout, dests, destfd, destoffsets, part, °raded, buf); validate(afd, destfd[0], destoffsets[0]); /* record where 'part' is up to */ part = !part; if (increasing) backup_point += actual_stripes * (chunk/512) * data; else backup_point -= actual_stripes * (chunk/512) * data; } } /* FIXME maybe call progress_reshape one more time instead */ /* remove any remaining suspension */ sysfs_set_num(sra, NULL, "suspend_lo", 0x7FFFFFFFFFFFFFFFULL); sysfs_set_num(sra, NULL, "suspend_hi", 0); sysfs_set_num(sra, NULL, "suspend_lo", 0); sysfs_set_num(sra, NULL, "sync_min", 0); free(buf); return done; } /* * If any spare contains md_back_data-1 which is recent wrt mtime, * write that data into the array and update the super blocks with * the new reshape_progress */ int Grow_restart(struct supertype *st, struct mdinfo *info, int *fdlist, int cnt, char *backup_file, int verbose) { int i, j; int old_disks; unsigned long long *offsets; unsigned long long nstripe, ostripe; int ndata, odata; int fd, backup_fd = -1; odata = info->array.raid_disks - info->delta_disks - 1; if (info->array.level == 6) odata--; /* number of data disks */ ndata = info->array.raid_disks - 1; if (info->new_level == 6) ndata--; old_disks = info->array.raid_disks - info->delta_disks; if (info->delta_disks <= 0) /* Didn't grow, so the backup file must have * been used */ old_disks = cnt; if (backup_file) { backup_fd = open(backup_file, O_RDONLY); if (!is_fd_valid(backup_fd)) { pr_err("Can't open backup file %s : %s\n", backup_file, strerror(errno)); return -EINVAL; } } for (i=old_disks-(backup_file?1:0); iss->load_super(st, fd, NULL)) continue; st->ss->getinfo_super(st, &dinfo, NULL); st->ss->free_super(st); if (lseek64(fd, (dinfo.data_offset + dinfo.component_size - 8) <<9, 0) < 0) { pr_err("Cannot seek on device %d\n", i); continue; /* Cannot seek */ } sprintf(namebuf, "device-%d", i); devname = namebuf; } if (read(fd, &bsb, sizeof(bsb)) != sizeof(bsb)) { if (verbose) pr_err("Cannot read from %s\n", devname); continue; /* Cannot read */ } if (memcmp(bsb.magic, "md_backup_data-1", 16) != 0 && memcmp(bsb.magic, "md_backup_data-2", 16) != 0) { if (verbose) pr_err("No backup metadata on %s\n", devname); continue; } if (bsb.sb_csum != bsb_csum((char*)&bsb, ((char*)&bsb.sb_csum)-((char*)&bsb))) { if (verbose) pr_err("Bad backup-metadata checksum on %s\n", devname); continue; /* bad checksum */ } if (memcmp(bsb.magic, "md_backup_data-2", 16) == 0 && bsb.sb_csum2 != bsb_csum((char*)&bsb, ((char*)&bsb.sb_csum2)-((char*)&bsb))) { if (verbose) pr_err("Bad backup-metadata checksum2 on %s\n", devname); continue; /* Bad second checksum */ } if (memcmp(bsb.set_uuid,info->uuid, 16) != 0) { if (verbose) pr_err("Wrong uuid on backup-metadata on %s\n", devname); continue; /* Wrong uuid */ } /* * array utime and backup-mtime should be updated at * much the same time, but it seems that sometimes * they aren't... So allow considerable flexability in * matching, and allow this test to be overridden by * an environment variable. */ if(time_after(info->array.utime, (unsigned int)__le64_to_cpu(bsb.mtime) + 2*60*60) || time_before(info->array.utime, (unsigned int)__le64_to_cpu(bsb.mtime) - 10*60)) { if (check_env("MDADM_GROW_ALLOW_OLD")) { pr_err("accepting backup with timestamp %lu for array with timestamp %lu\n", (unsigned long)__le64_to_cpu(bsb.mtime), (unsigned long)info->array.utime); } else { pr_err("too-old timestamp on backup-metadata on %s\n", devname); pr_err("If you think it is should be safe, try 'export MDADM_GROW_ALLOW_OLD=1'\n"); continue; /* time stamp is too bad */ } } if (bsb.magic[15] == '1') { if (bsb.length == 0) continue; if (info->delta_disks >= 0) { /* reshape_progress is increasing */ if (__le64_to_cpu(bsb.arraystart) + __le64_to_cpu(bsb.length) < info->reshape_progress) { nonew: if (verbose) pr_err("backup-metadata found on %s but is not needed\n", devname); continue; /* No new data here */ } } else { /* reshape_progress is decreasing */ if (__le64_to_cpu(bsb.arraystart) >= info->reshape_progress) goto nonew; /* No new data here */ } } else { if (bsb.length == 0 && bsb.length2 == 0) continue; if (info->delta_disks >= 0) { /* reshape_progress is increasing */ if ((__le64_to_cpu(bsb.arraystart) + __le64_to_cpu(bsb.length) < info->reshape_progress) && (__le64_to_cpu(bsb.arraystart2) + __le64_to_cpu(bsb.length2) < info->reshape_progress)) goto nonew; /* No new data here */ } else { /* reshape_progress is decreasing */ if (__le64_to_cpu(bsb.arraystart) >= info->reshape_progress && __le64_to_cpu(bsb.arraystart2) >= info->reshape_progress) goto nonew; /* No new data here */ } } if (lseek64(fd, __le64_to_cpu(bsb.devstart)*512, 0)< 0) { second_fail: if (verbose) pr_err("Failed to verify secondary backup-metadata block on %s\n", devname); continue; /* Cannot seek */ } /* There should be a duplicate backup superblock 4k before here */ if (lseek64(fd, -4096, 1) < 0 || read(fd, &bsb2, sizeof(bsb2)) != sizeof(bsb2)) goto second_fail; /* Cannot find leading superblock */ if (bsb.magic[15] == '1') bsbsize = offsetof(struct mdp_backup_super, pad1); else bsbsize = offsetof(struct mdp_backup_super, pad); if (memcmp(&bsb2, &bsb, bsbsize) != 0) goto second_fail; /* Cannot find leading superblock */ /* Now need the data offsets for all devices. */ offsets = xmalloc(sizeof(*offsets)*info->array.raid_disks); for(j=0; jarray.raid_disks; j++) { if (fdlist[j] < 0) continue; if (st->ss->load_super(st, fdlist[j], NULL)) /* FIXME should be this be an error */ continue; st->ss->getinfo_super(st, &dinfo, NULL); st->ss->free_super(st); offsets[j] = dinfo.data_offset * 512; } printf("%s: restoring critical section\n", Name); if (restore_stripes(fdlist, offsets, info->array.raid_disks, info->new_chunk, info->new_level, info->new_layout, fd, __le64_to_cpu(bsb.devstart)*512, __le64_to_cpu(bsb.arraystart)*512, __le64_to_cpu(bsb.length)*512, NULL)) { /* didn't succeed, so giveup */ if (verbose) pr_err("Error restoring backup from %s\n", devname); free(offsets); close_fd(&backup_fd); return 1; } if (bsb.magic[15] == '2' && restore_stripes(fdlist, offsets, info->array.raid_disks, info->new_chunk, info->new_level, info->new_layout, fd, __le64_to_cpu(bsb.devstart)*512 + __le64_to_cpu(bsb.devstart2)*512, __le64_to_cpu(bsb.arraystart2)*512, __le64_to_cpu(bsb.length2)*512, NULL)) { /* didn't succeed, so giveup */ if (verbose) pr_err("Error restoring second backup from %s\n", devname); free(offsets); close_fd(&backup_fd); return 1; } free(offsets); /* Ok, so the data is restored. Let's update those superblocks. */ lo = hi = 0; if (bsb.length) { lo = __le64_to_cpu(bsb.arraystart); hi = lo + __le64_to_cpu(bsb.length); } if (bsb.magic[15] == '2' && bsb.length2) { unsigned long long lo1, hi1; lo1 = __le64_to_cpu(bsb.arraystart2); hi1 = lo1 + __le64_to_cpu(bsb.length2); if (lo == hi) { lo = lo1; hi = hi1; } else if (lo < lo1) hi = hi1; else lo = lo1; } if (lo < hi && (info->reshape_progress < lo || info->reshape_progress > hi)) /* backup does not affect reshape_progress*/ ; else if (info->delta_disks >= 0) { info->reshape_progress = __le64_to_cpu(bsb.arraystart) + __le64_to_cpu(bsb.length); if (bsb.magic[15] == '2') { unsigned long long p2; p2 = __le64_to_cpu(bsb.arraystart2) + __le64_to_cpu(bsb.length2); if (p2 > info->reshape_progress) info->reshape_progress = p2; } } else { info->reshape_progress = __le64_to_cpu(bsb.arraystart); if (bsb.magic[15] == '2') { unsigned long long p2; p2 = __le64_to_cpu(bsb.arraystart2); if (p2 < info->reshape_progress) info->reshape_progress = p2; } } for (j=0; jarray.raid_disks; j++) { if (fdlist[j] < 0) continue; if (st->ss->load_super(st, fdlist[j], NULL)) continue; st->ss->getinfo_super(st, &dinfo, NULL); dinfo.reshape_progress = info->reshape_progress; st->ss->update_super(st, &dinfo, UOPT_SPEC__RESHAPE_PROGRESS, NULL,0, 0, NULL); st->ss->store_super(st, fdlist[j]); st->ss->free_super(st); } close_fd(&backup_fd); return 0; } close_fd(&backup_fd); /* Didn't find any backup data, try to see if any * was needed. */ if (info->delta_disks < 0) { /* When shrinking, the critical section is at the end. * So see if we are before the critical section. */ unsigned long long first_block; nstripe = ostripe = 0; first_block = 0; while (ostripe >= nstripe) { ostripe += info->array.chunk_size / 512; first_block = ostripe * odata; nstripe = first_block / ndata / (info->new_chunk/512) * (info->new_chunk/512); } if (info->reshape_progress >= first_block) return 0; } if (info->delta_disks > 0) { /* See if we are beyond the critical section. */ unsigned long long last_block; nstripe = ostripe = 0; last_block = 0; while (nstripe >= ostripe) { nstripe += info->new_chunk / 512; last_block = nstripe * ndata; ostripe = last_block / odata / (info->array.chunk_size/512) * (info->array.chunk_size/512); } if (info->reshape_progress >= last_block) return 0; } /* needed to recover critical section! */ if (verbose) pr_err("Failed to find backup of critical section\n"); return 1; } int Grow_continue_command(char *devname, int fd, struct context *c) { int ret_val = 0; struct supertype *st = NULL; struct mdinfo *content = NULL; struct mdinfo array; char *subarray = NULL; struct mdinfo *cc = NULL; struct mdstat_ent *mdstat = NULL; int cfd = -1; int fd2; dprintf("Grow continue from command line called for %s\n", devname); st = super_by_fd(fd, &subarray); if (!st || !st->ss) { pr_err("Unable to determine metadata format for %s\n", devname); return 1; } dprintf("Grow continue is run for "); if (st->ss->external == 0) { int d; int cnt = 5; dprintf_cont("native array (%s)\n", devname); if (md_get_array_info(fd, &array.array) < 0) { pr_err("%s is not an active md array - aborting\n", devname); ret_val = 1; goto Grow_continue_command_exit; } content = &array; if (sysfs_init(content, fd, NULL) < 0) { pr_err("sysfs_init fails\n"); ret_val = 1; goto Grow_continue_command_exit; } /* Need to load a superblock. * FIXME we should really get what we need from * sysfs */ do { for (d = 0; d < MAX_DISKS; d++) { mdu_disk_info_t disk; char *dv; int err; disk.number = d; if (md_get_disk_info(fd, &disk) < 0) continue; if (disk.major == 0 && disk.minor == 0) continue; if ((disk.state & (1 << MD_DISK_ACTIVE)) == 0) continue; dv = map_dev(disk.major, disk.minor, 1); if (!dv) continue; fd2 = dev_open(dv, O_RDONLY); if (fd2 < 0) continue; err = st->ss->load_super(st, fd2, NULL); close(fd2); if (err) continue; break; } if (d == MAX_DISKS) { pr_err("Unable to load metadata for %s\n", devname); ret_val = 1; goto Grow_continue_command_exit; } st->ss->getinfo_super(st, content, NULL); if (!content->reshape_active) sleep_for(3, 0, true); else break; } while (cnt-- > 0); } else { char *container; if (subarray) { dprintf_cont("subarray (%s)\n", subarray); container = st->container_devnm; cfd = open_dev_excl(st->container_devnm); } else { container = st->devnm; close(fd); cfd = open_dev_excl(st->devnm); dprintf_cont("container (%s)\n", container); fd = cfd; } if (cfd < 0) { pr_err("Unable to open container for %s\n", devname); ret_val = 1; goto Grow_continue_command_exit; } /* find in container array under reshape */ ret_val = st->ss->load_container(st, cfd, NULL); if (ret_val) { pr_err("Cannot read superblock for %s\n", devname); ret_val = 1; goto Grow_continue_command_exit; } cc = st->ss->container_content(st, subarray); for (content = cc; content ; content = content->next) { char *array_name; int allow_reshape = 1; if (content->reshape_active == 0) continue; /* The decision about array or container wide * reshape is taken in Grow_continue based * content->reshape_active state, therefore we * need to check_reshape based on * reshape_active and subarray name */ if (content->array.state & (1<reshape_active == CONTAINER_RESHAPE && (content->array.state & (1<text_version+1, '/')+1; mdstat = mdstat_by_subdev(array_name, container); if (!mdstat) continue; if (mdstat->active == 0) { pr_err("Skipping inactive array %s.\n", mdstat->devnm); free_mdstat(mdstat); mdstat = NULL; continue; } break; } if (!content) { pr_err("Unable to determine reshaped array for %s\n", devname); ret_val = 1; goto Grow_continue_command_exit; } fd2 = open_dev(mdstat->devnm); if (fd2 < 0) { pr_err("cannot open (%s)\n", mdstat->devnm); ret_val = 1; goto Grow_continue_command_exit; } if (sysfs_init(content, fd2, mdstat->devnm)) { pr_err("Unable to initialize sysfs for %s, Grow cannot continue.\n", mdstat->devnm); ret_val = 1; close(fd2); goto Grow_continue_command_exit; } close(fd2); /* start mdmon in case it is not running */ if (!mdmon_running(container)) start_mdmon(container); ping_monitor(container); if (wait_for_mdmon(container) != MDADM_STATUS_SUCCESS) { pr_err("No mdmon found. Grow cannot continue.\n"); ret_val = 1; goto Grow_continue_command_exit; } } /* verify that array under reshape is started from * correct position */ if (verify_reshape_position(content, content->array.level) < 0) { ret_val = 1; goto Grow_continue_command_exit; } /* continue reshape */ ret_val = Grow_continue(fd, st, content, 1, c); Grow_continue_command_exit: if (cfd > -1) close(cfd); st->ss->free_super(st); free_mdstat(mdstat); sysfs_free(cc); free(subarray); return ret_val; } int Grow_continue(int mdfd, struct supertype *st, struct mdinfo *info, int forked, struct context *c) { int ret_val = 2; if (!info->reshape_active) return ret_val; if (st->ss->external) { int cfd = open_dev(st->container_devnm); if (cfd < 0) return 1; st->ss->load_container(st, cfd, st->container_devnm); close(cfd); ret_val = reshape_container(st->container_devnm, NULL, mdfd, st, info, c, forked, 1 | info->reshape_active); } else ret_val = reshape_array(NULL, mdfd, "array", st, info, 1, NULL, INVALID_SECTORS, c->backup_file, 0, forked, 1 | info->reshape_active, c->freeze_reshape); return ret_val; } char *make_backup(char *name) { char *base = "backup_file-"; int len; char *fname; len = strlen(MAP_DIR) + 1 + strlen(base) + strlen(name)+1; fname = xmalloc(len); sprintf(fname, "%s/%s%s", MAP_DIR, base, name); return fname; } char *locate_backup(char *name) { char *fl = make_backup(name); struct stat stb; if (stat(fl, &stb) == 0 && S_ISREG(stb.st_mode)) return fl; free(fl); return NULL; }