/* * mdadm - manage Linux "md" devices aka RAID arrays. * * Copyright (C) 2001-2006 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: * Paper: Neil Brown * School of Computer Science and Engineering * The University of New South Wales * Sydney, 2052 * Australia */ #define HAVE_STDINT_H 1 #include "mdadm.h" #include "sha1.h" /* * All handling for the 0.90.0 version superblock is in * this file. * This includes: * - finding, loading, and writing the superblock. * - initialising a new superblock * - printing the superblock for --examine * - printing part of the superblock for --detail * .. other stuff */ static unsigned long calc_sb0_csum(mdp_super_t *super) { unsigned long csum = super->sb_csum; unsigned long newcsum; super->sb_csum= 0 ; newcsum = calc_csum(super, MD_SB_BYTES); super->sb_csum = csum; return newcsum; } static void super0_swap_endian(struct mdp_superblock_s *sb) { /* as super0 superblocks are host-endian, it is sometimes * useful to be able to swap the endianness * as (almost) everything is u32's we byte-swap every 4byte * number. * We then also have to swap the events_hi and events_lo */ char *sbc = (char *)sb; __u32 t32; int i; for (i=0; i < MD_SB_BYTES ; i+=4) { char t = sbc[i]; sbc[i] = sbc[i+3]; sbc[i+3] = t; t=sbc[i+1]; sbc[i+1]=sbc[i+2]; sbc[i+2]=t; } t32 = sb->events_hi; sb->events_hi = sb->events_lo; sb->events_lo = t32; t32 = sb->cp_events_hi; sb->cp_events_hi = sb->cp_events_lo; sb->cp_events_lo = t32; } #ifndef MDASSEMBLE static void examine_super0(struct supertype *st, char *homehost) { mdp_super_t *sb = st->sb; time_t atime; int d; char *c; printf(" Magic : %08x\n", sb->md_magic); printf(" Version : %02d.%02d.%02d\n", sb->major_version, sb->minor_version, sb->patch_version); if (sb->minor_version >= 90) { printf(" UUID : %08x:%08x:%08x:%08x", sb->set_uuid0, sb->set_uuid1, sb->set_uuid2, sb->set_uuid3); if (homehost) { char buf[20]; void *hash = sha1_buffer(homehost, strlen(homehost), buf); if (memcmp(&sb->set_uuid2, hash, 8)==0) printf(" (local to host %s)", homehost); } printf("\n"); } else printf(" UUID : %08x\n", sb->set_uuid0); if (sb->not_persistent) printf(" Eedk : not persistent\n"); atime = sb->ctime; printf(" Creation Time : %.24s\n", ctime(&atime)); c=map_num(pers, sb->level); printf(" Raid Level : %s\n", c?c:"-unknown-"); if ((int)sb->level >= 0) { int ddsks=0; printf(" Used Dev Size : %d%s\n", sb->size, human_size((long long)sb->size<<10)); switch(sb->level) { case 1: ddsks=1;break; case 4: case 5: ddsks = sb->raid_disks-1; break; case 6: ddsks = sb->raid_disks-2; break; case 10: ddsks = sb->raid_disks / (sb->layout&255) / ((sb->layout>>8)&255); } if (ddsks) printf(" Array Size : %llu%s\n", (unsigned long long)ddsks * sb->size, human_size(ddsks*(long long)sb->size<<10)); } printf(" Raid Devices : %d\n", sb->raid_disks); printf(" Total Devices : %d\n", sb->nr_disks); printf("Preferred Minor : %d\n", sb->md_minor); printf("\n"); if (sb->minor_version > 90 && (sb->reshape_position+1) != 0) { printf(" Reshape pos'n : %llu%s\n", (unsigned long long)sb->reshape_position/2, human_size((long long)sb->reshape_position<<9)); if (sb->delta_disks) { printf(" Delta Devices : %d", sb->delta_disks); if (sb->delta_disks) printf(" (%d->%d)\n", sb->raid_disks-sb->delta_disks, sb->raid_disks); else printf(" (%d->%d)\n", sb->raid_disks, sb->raid_disks+sb->delta_disks); } if (sb->new_level != sb->level) { c = map_num(pers, sb->new_level); printf(" New Level : %s\n", c?c:"-unknown-"); } if (sb->new_layout != sb->layout) { if (sb->level == 5) { c = map_num(r5layout, sb->new_layout); printf(" New Layout : %s\n", c?c:"-unknown-"); } if (sb->level == 10) { printf(" New Layout : near=%d, %s=%d\n", sb->new_layout&255, (sb->new_layout&0x10000)?"offset":"far", (sb->new_layout>>8)&255); } } if (sb->new_chunk != sb->chunk_size) printf(" New Chunksize : %d\n", sb->new_chunk); printf("\n"); } atime = sb->utime; printf(" Update Time : %.24s\n", ctime(&atime)); printf(" State : %s\n", (sb->state&(1<state & (1<active_disks); printf("Working Devices : %d\n", sb->working_disks); printf(" Failed Devices : %d\n", sb->failed_disks); printf(" Spare Devices : %d\n", sb->spare_disks); if (calc_sb0_csum(sb) == sb->sb_csum) printf(" Checksum : %x - correct\n", sb->sb_csum); else printf(" Checksum : %x - expected %lx\n", sb->sb_csum, calc_sb0_csum(sb)); printf(" Events : %llu\n", ((unsigned long long)sb->events_hi << 32) + sb->events_lo); printf("\n"); if (sb->level == 5) { c = map_num(r5layout, sb->layout); printf(" Layout : %s\n", c?c:"-unknown-"); } if (sb->level == 10) { printf(" Layout : near=%d, %s=%d\n", sb->layout&255, (sb->layout&0x10000)?"offset":"far", (sb->layout>>8)&255); } switch(sb->level) { case 0: case 4: case 5: case 6: case 10: printf(" Chunk Size : %dK\n", sb->chunk_size/1024); break; case -1: printf(" Rounding : %dK\n", sb->chunk_size/1024); break; default: break; } printf("\n"); printf(" Number Major Minor RaidDevice State\n"); for (d= -1; d<(signed int)(sb->raid_disks+sb->spare_disks); d++) { mdp_disk_t *dp; char *dv; char nb[5]; int wonly; if (d>=0) dp = &sb->disks[d]; else dp = &sb->this_disk; snprintf(nb, sizeof(nb), "%4d", d); printf("%4s %5d %5d %5d %5d ", d < 0 ? "this" : nb, dp->number, dp->major, dp->minor, dp->raid_disk); wonly = dp->state & (1<state &= ~(1<state & (1<state & (1<state & (1<state & (1<state == 0) printf(" spare"); if ((dv=map_dev(dp->major, dp->minor, 0))) printf(" %s", dv); printf("\n"); if (d == -1) printf("\n"); } } static void brief_examine_super0(struct supertype *st) { mdp_super_t *sb = st->sb; char *c=map_num(pers, sb->level); char devname[20]; sprintf(devname, "/dev/md%d", sb->md_minor); printf("ARRAY %s level=%s num-devices=%d UUID=", devname, c?c:"-unknown-", sb->raid_disks); if (sb->minor_version >= 90) printf("%08x:%08x:%08x:%08x", sb->set_uuid0, sb->set_uuid1, sb->set_uuid2, sb->set_uuid3); else printf("%08x", sb->set_uuid0); printf("\n"); } static void export_examine_super0(struct supertype *st) { mdp_super_t *sb = st->sb; printf("MD_LEVEL=%s\n", map_num(pers, sb->level)); printf("MD_DEVICES=%d\n", sb->raid_disks); if (sb->minor_version >= 90) printf("MD_UUID=%08x:%08x:%08x:%08x\n", sb->set_uuid0, sb->set_uuid1, sb->set_uuid2, sb->set_uuid3); else printf("MD_UUID=%08x\n", sb->set_uuid0); printf("MD_UPDATE_TIME=%llu\n", __le64_to_cpu(sb->ctime) & 0xFFFFFFFFFFULL); printf("MD_EVENTS=%llu\n", ((unsigned long long)sb->events_hi << 32) + sb->events_lo); } static void detail_super0(struct supertype *st, char *homehost) { mdp_super_t *sb = st->sb; printf(" UUID : "); if (sb->minor_version >= 90) printf("%08x:%08x:%08x:%08x", sb->set_uuid0, sb->set_uuid1, sb->set_uuid2, sb->set_uuid3); else printf("%08x", sb->set_uuid0); if (homehost) { char buf[20]; void *hash = sha1_buffer(homehost, strlen(homehost), buf); if (memcmp(&sb->set_uuid2, hash, 8)==0) printf(" (local to host %s)", homehost); } printf("\n Events : %d.%d\n\n", sb->events_hi, sb->events_lo); } static void brief_detail_super0(struct supertype *st) { mdp_super_t *sb = st->sb; printf(" UUID="); if (sb->minor_version >= 90) printf("%08x:%08x:%08x:%08x", sb->set_uuid0, sb->set_uuid1, sb->set_uuid2, sb->set_uuid3); else printf("%08x", sb->set_uuid0); } static void export_detail_super0(struct supertype *st) { mdp_super_t *sb = st->sb; printf("MD_UUID="); if (sb->minor_version >= 90) printf("%08x:%08x:%08x:%08x", sb->set_uuid0, sb->set_uuid1, sb->set_uuid2, sb->set_uuid3); else printf("%08x", sb->set_uuid0); printf("\n"); } #endif static int match_home0(struct supertype *st, char *homehost) { mdp_super_t *sb = st->sb; char buf[20]; char *hash = sha1_buffer(homehost, strlen(homehost), buf); return (memcmp(&sb->set_uuid2, hash, 8)==0); } static void uuid_from_super0(struct supertype *st, int uuid[4]) { mdp_super_t *super = st->sb; uuid[0] = super->set_uuid0; if (super->minor_version >= 90) { uuid[1] = super->set_uuid1; uuid[2] = super->set_uuid2; uuid[3] = super->set_uuid3; } else { uuid[1] = 0; uuid[2] = 0; uuid[3] = 0; } } static void getinfo_super0(struct supertype *st, struct mdinfo *info) { mdp_super_t *sb = st->sb; int working = 0; int i; info->array.major_version = sb->major_version; info->array.minor_version = sb->minor_version; info->array.patch_version = sb->patch_version; info->array.raid_disks = sb->raid_disks; info->array.level = sb->level; info->array.layout = sb->layout; info->array.md_minor = sb->md_minor; info->array.ctime = sb->ctime; info->array.utime = sb->utime; info->array.chunk_size = sb->chunk_size; info->array.state = sb->state; info->component_size = sb->size*2; info->disk.state = sb->this_disk.state; info->disk.major = sb->this_disk.major; info->disk.minor = sb->this_disk.minor; info->disk.raid_disk = sb->this_disk.raid_disk; info->disk.number = sb->this_disk.number; info->events = md_event(sb); info->data_offset = 0; sprintf(info->text_version, "0.%d", sb->minor_version); uuid_from_super0(st, info->uuid); if (sb->minor_version > 90 && (sb->reshape_position+1) != 0) { info->reshape_active = 1; info->reshape_progress = sb->reshape_position; info->new_level = sb->new_level; info->delta_disks = sb->delta_disks; info->new_layout = sb->new_layout; info->new_chunk = sb->new_chunk; } else info->reshape_active = 0; sprintf(info->name, "%d", sb->md_minor); /* work_disks is calculated rather than read directly */ for (i=0; i < MD_SB_DISKS; i++) if ((sb->disks[i].state & (1<disks[i].raid_disk < info->array.raid_disks) && (sb->disks[i].state & (1<disks[i].state & (1<array.working_disks = working; } static int update_super0(struct supertype *st, struct mdinfo *info, char *update, char *devname, int verbose, int uuid_set, char *homehost) { /* NOTE: for 'assemble' and 'force' we need to return non-zero if any change was made. * For others, the return value is ignored. */ int rv = 0; mdp_super_t *sb = st->sb; if (strcmp(update, "sparc2.2")==0 ) { /* 2.2 sparc put the events in the wrong place * So we copy the tail of the superblock * up 4 bytes before continuing */ __u32 *sb32 = (__u32*)sb; memcpy(sb32+MD_SB_GENERIC_CONSTANT_WORDS+7, sb32+MD_SB_GENERIC_CONSTANT_WORDS+7+1, (MD_SB_WORDS - (MD_SB_GENERIC_CONSTANT_WORDS+7+1))*4); if (verbose >= 0) fprintf (stderr, Name ": adjusting superblock of %s for 2.2/sparc compatability.\n", devname); } if (strcmp(update, "super-minor") ==0) { sb->md_minor = info->array.md_minor; if (verbose > 0) fprintf(stderr, Name ": updating superblock of %s with minor number %d\n", devname, info->array.md_minor); } if (strcmp(update, "summaries") == 0) { int i; /* set nr_disks, active_disks, working_disks, * failed_disks, spare_disks based on disks[] * array in superblock. * Also make sure extra slots aren't 'failed' */ sb->nr_disks = sb->active_disks = sb->working_disks = sb->failed_disks = sb->spare_disks = 0; for (i=0; i < MD_SB_DISKS ; i++) if (sb->disks[i].major || sb->disks[i].minor) { int state = sb->disks[i].state; if (state & (1<nr_disks++; if (state & (1<active_disks++; if (state & (1<failed_disks++; else sb->working_disks++; if (state == 0) sb->spare_disks++; } else if (i >= sb->raid_disks && sb->disks[i].number == 0) sb->disks[i].state = 0; } if (strcmp(update, "force-one")==0) { /* Not enough devices for a working array, so * bring this one up-to-date. */ __u32 ehi = sb->events_hi, elo = sb->events_lo; sb->events_hi = (info->events>>32) & 0xFFFFFFFF; sb->events_lo = (info->events) & 0xFFFFFFFF; if (sb->events_hi != ehi || sb->events_lo != elo) rv = 1; } if (strcmp(update, "force-array")==0) { /* degraded array and 'force' requested, so * maybe need to mark it 'clean' */ if ((sb->level == 5 || sb->level == 4 || sb->level == 6) && (sb->state & (1 << MD_SB_CLEAN)) == 0) { /* need to force clean */ sb->state |= (1 << MD_SB_CLEAN); rv = 1; } } if (strcmp(update, "assemble")==0) { int d = info->disk.number; int wonly = sb->disks[d].state & (1<disks[d].state & ~(1<disk.state) { sb->disks[d].state = info->disk.state | wonly; rv = 1; } } if (strcmp(update, "linear-grow-new") == 0) { memset(&sb->disks[info->disk.number], 0, sizeof(sb->disks[0])); sb->disks[info->disk.number].number = info->disk.number; sb->disks[info->disk.number].major = info->disk.major; sb->disks[info->disk.number].minor = info->disk.minor; sb->disks[info->disk.number].raid_disk = info->disk.raid_disk; sb->disks[info->disk.number].state = info->disk.state; sb->this_disk = sb->disks[info->disk.number]; } if (strcmp(update, "linear-grow-update") == 0) { sb->raid_disks = info->array.raid_disks; sb->nr_disks = info->array.nr_disks; sb->active_disks = info->array.active_disks; sb->working_disks = info->array.working_disks; memset(&sb->disks[info->disk.number], 0, sizeof(sb->disks[0])); sb->disks[info->disk.number].number = info->disk.number; sb->disks[info->disk.number].major = info->disk.major; sb->disks[info->disk.number].minor = info->disk.minor; sb->disks[info->disk.number].raid_disk = info->disk.raid_disk; sb->disks[info->disk.number].state = info->disk.state; } if (strcmp(update, "resync") == 0) { /* make sure resync happens */ sb->state &= ~(1<recovery_cp = 0; } if (strcmp(update, "homehost") == 0 && homehost) { uuid_set = 0; update = "uuid"; info->uuid[0] = sb->set_uuid0; info->uuid[1] = sb->set_uuid1; } if (strcmp(update, "uuid") == 0) { if (!uuid_set && homehost) { char buf[20]; char *hash = sha1_buffer(homehost, strlen(homehost), buf); memcpy(info->uuid+2, hash, 8); } sb->set_uuid0 = info->uuid[0]; sb->set_uuid1 = info->uuid[1]; sb->set_uuid2 = info->uuid[2]; sb->set_uuid3 = info->uuid[3]; if (sb->state & (1<uuid); } } if (strcmp(update, "_reshape_progress")==0) sb->reshape_position = info->reshape_progress; sb->sb_csum = calc_sb0_csum(sb); return rv; } /* * For verion-0 superblock, the homehost is 'stored' in the * uuid. 8 bytes for a hash of the host leaving 8 bytes * of random material. * We use the first 8 bytes (64bits) of the sha1 of the * host name */ static int init_super0(struct supertype *st, mdu_array_info_t *info, unsigned long long size, char *ignored_name, char *homehost, int *uuid) { mdp_super_t *sb; int spares; posix_memalign((void**)&sb, 512, MD_SB_BYTES + sizeof(bitmap_super_t)); memset(sb, 0, MD_SB_BYTES + sizeof(bitmap_super_t)); st->sb = sb; if (info == NULL) { /* zeroing the superblock */ return 0; } spares = info->working_disks - info->active_disks; if (info->raid_disks + spares > MD_SB_DISKS) { fprintf(stderr, Name ": too many devices requested: %d+%d > %d\n", info->raid_disks , spares, MD_SB_DISKS); return 0; } sb->md_magic = MD_SB_MAGIC; sb->major_version = 0; sb->minor_version = 90; sb->patch_version = 0; sb->gvalid_words = 0; /* ignored */ sb->ctime = time(0); sb->level = info->level; if (size != info->size) return 0; sb->size = info->size; sb->nr_disks = info->nr_disks; sb->raid_disks = info->raid_disks; sb->md_minor = info->md_minor; sb->not_persistent = 0; if (uuid) { sb->set_uuid0 = uuid[0]; sb->set_uuid1 = uuid[1]; sb->set_uuid2 = uuid[2]; sb->set_uuid3 = uuid[3]; } else { int rfd = open("/dev/urandom", O_RDONLY); if (rfd < 0 || read(rfd, &sb->set_uuid0, 4) != 4) sb->set_uuid0 = random(); if (rfd < 0 || read(rfd, &sb->set_uuid1, 12) != 12) { sb->set_uuid1 = random(); sb->set_uuid2 = random(); sb->set_uuid3 = random(); } if (rfd >= 0) close(rfd); } if (homehost) { char buf[20]; char *hash = sha1_buffer(homehost, strlen(homehost), buf); memcpy(&sb->set_uuid2, hash, 8); } sb->utime = sb->ctime; sb->state = info->state; sb->active_disks = info->active_disks; sb->working_disks = info->working_disks; sb->failed_disks = info->failed_disks; sb->spare_disks = info->spare_disks; sb->events_hi = 0; sb->events_lo = 1; sb->layout = info->layout; sb->chunk_size = info->chunk_size; return 1; } struct devinfo { int fd; char *devname; mdu_disk_info_t disk; struct devinfo *next; }; /* Add a device to the superblock being created */ static void add_to_super0(struct supertype *st, mdu_disk_info_t *dinfo, int fd, char *devname) { mdp_super_t *sb = st->sb; mdp_disk_t *dk = &sb->disks[dinfo->number]; struct devinfo *di, **dip; dk->number = dinfo->number; dk->major = dinfo->major; dk->minor = dinfo->minor; dk->raid_disk = dinfo->raid_disk; dk->state = dinfo->state; sb->this_disk = sb->disks[dinfo->number]; sb->sb_csum = calc_sb0_csum(sb); dip = (struct devinfo **)&st->info; while (*dip) dip = &(*dip)->next; di = malloc(sizeof(struct devinfo)); di->fd = fd; di->devname = devname; di->disk = *dinfo; di->next = NULL; *dip = di; } static int store_super0(struct supertype *st, int fd) { unsigned long long dsize; unsigned long long offset; mdp_super_t *super = st->sb; if (!get_dev_size(fd, NULL, &dsize)) return 1; if (dsize < MD_RESERVED_SECTORS*512) return 2; offset = MD_NEW_SIZE_SECTORS(dsize>>9); offset *= 512; if (lseek64(fd, offset, 0)< 0LL) return 3; if (write(fd, super, sizeof(*super)) != sizeof(*super)) return 4; if (super->state & (1<magic) == BITMAP_MAGIC) if (write(fd, bm, ROUND_UP(sizeof(*bm),512)) != ROUND_UP(sizeof(*bm),512)) return 5; } fsync(fd); return 0; } #ifndef MDASSEMBLE static int write_init_super0(struct supertype *st) { mdp_super_t *sb = st->sb; int rv = 0; struct devinfo *di; for (di = st->info ; di && ! rv ; di = di->next) { if (di->disk.state == 1) continue; if (di->fd == -1) continue; Kill(di->devname, 0, 1, 1); Kill(di->devname, 0, 1, 1); sb->disks[di->disk.number].state &= ~(1<this_disk = sb->disks[di->disk.number]; sb->sb_csum = calc_sb0_csum(sb); rv = store_super0(st, di->fd); if (rv == 0 && (sb->state & (1<ss->write_bitmap(st, di->fd); if (rv) fprintf(stderr, Name ": failed to write superblock to %s\n", di->devname); close(di->fd); di->fd = -1; } return rv; } #endif static int compare_super0(struct supertype *st, struct supertype *tst) { /* * return: * 0 same, or first was empty, and second was copied * 1 second had wrong number * 2 wrong uuid * 3 wrong other info */ mdp_super_t *first = st->sb; mdp_super_t *second = tst->sb; int uuid1[4], uuid2[4]; if (second->md_magic != MD_SB_MAGIC) return 1; if (!first) { posix_memalign((void**)&first, 512, MD_SB_BYTES + sizeof(struct bitmap_super_s)); memcpy(first, second, MD_SB_BYTES + sizeof(struct bitmap_super_s)); st->sb = first; return 0; } uuid_from_super0(st, uuid1); uuid_from_super0(tst, uuid2); if (!same_uuid(uuid1, uuid2, 0)) return 2; if (first->major_version != second->major_version || first->minor_version != second->minor_version || first->patch_version != second->patch_version || first->gvalid_words != second->gvalid_words || first->ctime != second->ctime || first->level != second->level || first->size != second->size || first->raid_disks != second->raid_disks ) return 3; return 0; } static void free_super0(struct supertype *st); static int load_super0(struct supertype *st, int fd, char *devname) { /* try to read in the superblock * Return: * 0 on success * 1 on cannot get superblock * 2 on superblock meaningless */ unsigned long long dsize; unsigned long long offset; mdp_super_t *super; int uuid[4]; struct bitmap_super_s *bsb; free_super0(st); if (st->subarray[0]) return 1; if (!get_dev_size(fd, devname, &dsize)) return 1; if (dsize < MD_RESERVED_SECTORS*512) { if (devname) fprintf(stderr, Name ": %s is too small for md: size is %llu sectors.\n", devname, dsize); return 1; } offset = MD_NEW_SIZE_SECTORS(dsize>>9); offset *= 512; ioctl(fd, BLKFLSBUF, 0); /* make sure we read current data */ if (lseek64(fd, offset, 0)< 0LL) { if (devname) fprintf(stderr, Name ": Cannot seek to superblock on %s: %s\n", devname, strerror(errno)); return 1; } posix_memalign((void**)&super, 512, MD_SB_BYTES + sizeof(bitmap_super_t)+512); if (read(fd, super, sizeof(*super)) != MD_SB_BYTES) { if (devname) fprintf(stderr, Name ": Cannot read superblock on %s\n", devname); free(super); return 1; } if (st->ss && st->minor_version == 9) super0_swap_endian(super); if (super->md_magic != MD_SB_MAGIC) { if (devname) fprintf(stderr, Name ": No super block found on %s (Expected magic %08x, got %08x)\n", devname, MD_SB_MAGIC, super->md_magic); free(super); return 2; } if (super->major_version != 0) { if (devname) fprintf(stderr, Name ": Cannot interpret superblock on %s - version is %d\n", devname, super->major_version); free(super); return 2; } st->sb = super; if (st->ss == NULL) { st->ss = &super0; st->minor_version = super->minor_version; st->max_devs = MD_SB_DISKS; st->info = NULL; } /* Now check on the bitmap superblock */ if ((super->state & (1<magic) != BITMAP_MAGIC || memcmp(bsb->uuid, uuid, 16) != 0) goto no_bitmap; return 0; no_bitmap: super->state &= ~(1<ss = &super0; st->info = NULL; st->minor_version = 90; st->max_devs = MD_SB_DISKS; st->sb = NULL; if (strcmp(arg, "0") == 0 || strcmp(arg, "0.90") == 0 || strcmp(arg, "default") == 0 || strcmp(arg, "") == 0 /* no metadata */ ) return st; st->minor_version = 91; /* reshape in progress */ if (strcmp(arg, "0.91") == 0) /* For dup_super support */ return st; st->minor_version = 9; /* flag for 'byte-swapped' */ if (strcmp(arg, "0.swap")==0 || strcmp(arg, "0.9") == 0) /* For dup_super support */ return st; free(st); return NULL; } static __u64 avail_size0(struct supertype *st, __u64 devsize) { if (devsize < MD_RESERVED_SECTORS) return 0ULL; return MD_NEW_SIZE_SECTORS(devsize); } static int add_internal_bitmap0(struct supertype *st, int *chunkp, int delay, int write_behind, unsigned long long size, int may_change, int major) { /* * The bitmap comes immediately after the superblock and must be 60K in size * at most. The default size is between 30K and 60K * * size is in sectors, chunk is in bytes !!! */ unsigned long long bits; unsigned long long max_bits = 60*1024*8; unsigned long long min_chunk; int chunk = *chunkp; mdp_super_t *sb = st->sb; bitmap_super_t *bms = (bitmap_super_t*)(((char*)sb) + MD_SB_BYTES); min_chunk = 4096; /* sub-page chunks don't work yet.. */ bits = (size * 512) / min_chunk + 1; while (bits > max_bits) { min_chunk *= 2; bits = (bits+1)/2; } if (chunk == UnSet) chunk = min_chunk; else if (chunk < min_chunk) return 0; /* chunk size too small */ sb->state |= (1<magic = __cpu_to_le32(BITMAP_MAGIC); bms->version = __cpu_to_le32(major); uuid_from_super0(st, (int*)bms->uuid); bms->chunksize = __cpu_to_le32(chunk); bms->daemon_sleep = __cpu_to_le32(delay); bms->sync_size = __cpu_to_le64(size); bms->write_behind = __cpu_to_le32(write_behind); *chunkp = chunk; return 1; } static void locate_bitmap0(struct supertype *st, int fd) { unsigned long long dsize; unsigned long long offset; if (!get_dev_size(fd, NULL, &dsize)) return; if (dsize < MD_RESERVED_SECTORS*512) return; offset = MD_NEW_SIZE_SECTORS(dsize>>9); offset *= 512; offset += MD_SB_BYTES; lseek64(fd, offset, 0); } static int write_bitmap0(struct supertype *st, int fd) { unsigned long long dsize; unsigned long long offset; mdp_super_t *sb = st->sb; int rv = 0; int towrite, n; char abuf[4096+512]; char *buf = (char*)(((long)(abuf+512))&~511UL); if (!get_dev_size(fd, NULL, &dsize)) return 1; if (dsize < MD_RESERVED_SECTORS*512) return -1; offset = MD_NEW_SIZE_SECTORS(dsize>>9); offset *= 512; if (lseek64(fd, offset + 4096, 0)< 0LL) return 3; memset(buf, 0xff, 4096); memcpy(buf, ((char*)sb)+MD_SB_BYTES, sizeof(bitmap_super_t)); towrite = 64*1024; while (towrite > 0) { n = towrite; if (n > 4096) n = 4096; n = write(fd, buf, n); if (n > 0) towrite -= n; else break; memset(buf, 0xff, 4096); } fsync(fd); if (towrite) rv = -2; return rv; } static void free_super0(struct supertype *st) { if (st->sb) free(st->sb); st->sb = NULL; } static int validate_geometry0(struct supertype *st, int level, int layout, int raiddisks, int chunk, unsigned long long size, char *subdev, unsigned long long *freesize) { unsigned long long ldsize; int fd; if (level == LEVEL_CONTAINER) return 0; if (raiddisks > MD_SB_DISKS) return 0; if (size > (0x7fffffffULL<<10)) return 0; if (!subdev) return 1; fd = open(subdev, O_RDONLY|O_EXCL, 0); if (fd < 0) { fprintf(stderr, Name ": Cannot open %s: %s\n", subdev, strerror(errno)); return 0; } if (!get_dev_size(fd, subdev, &ldsize)) { close(fd); return 0; } close(fd); if (ldsize < MD_RESERVED_SECTORS * 512) return 0; if (size > (0x7fffffffULL<<10)) return 0; *freesize = MD_NEW_SIZE_SECTORS(ldsize >> 9); return 1; } struct superswitch super0 = { #ifndef MDASSEMBLE .examine_super = examine_super0, .brief_examine_super = brief_examine_super0, .export_examine_super = export_examine_super0, .detail_super = detail_super0, .brief_detail_super = brief_detail_super0, .export_detail_super = export_detail_super0, .write_init_super = write_init_super0, #endif .match_home = match_home0, .uuid_from_super = uuid_from_super0, .getinfo_super = getinfo_super0, .update_super = update_super0, .init_super = init_super0, .add_to_super = add_to_super0, .store_super = store_super0, .compare_super = compare_super0, .load_super = load_super0, .match_metadata_desc = match_metadata_desc0, .avail_size = avail_size0, .add_internal_bitmap = add_internal_bitmap0, .locate_bitmap = locate_bitmap0, .write_bitmap = write_bitmap0, .free_super = free_super0, .validate_geometry = validate_geometry0, };