/* raid.c - module to read RAID arrays. */ /* * GRUB -- GRand Unified Bootloader * Copyright (C) 2006,2007,2008 Free Software Foundation, Inc. * * GRUB 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 3 of the License, or * (at your option) any later version. * * GRUB 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 GRUB. If not, see . */ #include #include #include #include #include #include /* Linked list of RAID arrays. */ static struct grub_raid_array *array_list; grub_raid5_recover_func_t grub_raid5_recover_func; grub_raid6_recover_func_t grub_raid6_recover_func; static char grub_is_array_readable (struct grub_raid_array *array) { switch (array->level) { case 0: if (array->nr_devs == array->total_devs) return 1; break; case 1: if (array->nr_devs >= 1) return 1; break; case 4: case 5: case 6: case 10: { unsigned int n; if (array->level == 10) { n = array->layout & 0xFF; if (n == 1) n = (array->layout >> 8) & 0xFF; n--; } else n = array->level / 3; if (array->nr_devs >= array->total_devs - n) return 1; break; } } return 0; } static int grub_raid_iterate (int (*hook) (const char *name)) { struct grub_raid_array *array; for (array = array_list; array != NULL; array = array->next) { if (grub_is_array_readable (array)) if (hook (array->name)) return 1; } return 0; } #ifdef GRUB_UTIL static grub_disk_memberlist_t grub_raid_memberlist (grub_disk_t disk) { struct grub_raid_array *array = disk->data; grub_disk_memberlist_t list = NULL, tmp; unsigned int i; for (i = 0; i < array->total_devs; i++) if (array->device[i]) { tmp = grub_malloc (sizeof (*tmp)); tmp->disk = array->device[i]; tmp->next = list; list = tmp; } return list; } #endif static grub_err_t grub_raid_open (const char *name, grub_disk_t disk) { struct grub_raid_array *array; unsigned n; for (array = array_list; array != NULL; array = array->next) { if (!grub_strcmp (array->name, name)) if (grub_is_array_readable (array)) break; } if (!array) return grub_error (GRUB_ERR_UNKNOWN_DEVICE, "Unknown RAID device %s", name); disk->has_partitions = 1; disk->id = array->number; disk->data = array; grub_dprintf ("raid", "%s: total_devs=%d, disk_size=%lld\n", name, array->total_devs, (unsigned long long) array->disk_size); switch (array->level) { case 1: disk->total_sectors = array->disk_size; break; case 10: n = array->layout & 0xFF; if (n == 1) n = (array->layout >> 8) & 0xFF; disk->total_sectors = grub_divmod64 (array->total_devs * array->disk_size, n, 0); break; case 0: case 4: case 5: case 6: n = array->level / 3; disk->total_sectors = (array->total_devs - n) * array->disk_size; break; } grub_dprintf ("raid", "%s: level=%d, total_sectors=%lld\n", name, array->level, (unsigned long long) disk->total_sectors); return 0; } static void grub_raid_close (grub_disk_t disk __attribute ((unused))) { return; } void grub_raid_block_xor (char *buf1, char *buf2, int size) { grub_size_t *p1, *p2; p1 = (grub_size_t *) buf1; p2 = (grub_size_t *) buf2; size /= GRUB_CPU_SIZEOF_VOID_P; while (size) { *(p1++) ^= *(p2++); size--; } } static grub_err_t grub_raid_read (grub_disk_t disk, grub_disk_addr_t sector, grub_size_t size, char *buf) { struct grub_raid_array *array = disk->data; grub_err_t err = 0; switch (array->level) { case 0: case 1: case 10: { grub_disk_addr_t read_sector, far_ofs; grub_uint32_t disknr, b, near, far, ofs; read_sector = grub_divmod64 (sector, array->chunk_size, &b); far = ofs = near = 1; far_ofs = 0; if (array->level == 1) near = array->total_devs; else if (array->level == 10) { near = array->layout & 0xFF; far = (array->layout >> 8) & 0xFF; if (array->layout >> 16) { ofs = far; far_ofs = 1; } else far_ofs = grub_divmod64 (array->disk_size, far * array->chunk_size, 0); far_ofs *= array->chunk_size; } read_sector = grub_divmod64 (read_sector * near, array->total_devs, &disknr); ofs *= array->chunk_size; read_sector *= ofs; while (1) { grub_size_t read_size; unsigned int i, j; read_size = array->chunk_size - b; if (read_size > size) read_size = size; for (i = 0; i < near; i++) { unsigned int k; k = disknr; for (j = 0; j < far; j++) { if (array->device[k]) { if (grub_errno == GRUB_ERR_READ_ERROR) grub_errno = GRUB_ERR_NONE; err = grub_disk_read (array->device[k], read_sector + j * far_ofs + b, 0, read_size << GRUB_DISK_SECTOR_BITS, buf); if (! err) break; else if (err != GRUB_ERR_READ_ERROR) return err; } else err = grub_error (GRUB_ERR_READ_ERROR, "disk missing."); k++; if (k == array->total_devs) k = 0; } if (! err) break; disknr++; if (disknr == array->total_devs) { disknr = 0; read_sector += ofs; } } if (err) return err; buf += read_size << GRUB_DISK_SECTOR_BITS; size -= read_size; if (! size) break; b = 0; disknr += (near - i); while (disknr >= array->total_devs) { disknr -= array->total_devs; read_sector += ofs; } } break; } case 4: case 5: case 6: { grub_disk_addr_t read_sector; grub_uint32_t b, p, n, disknr, e; /* n = 1 for level 4 and 5, 2 for level 6. */ n = array->level / 3; /* Find the first sector to read. */ read_sector = grub_divmod64 (sector, array->chunk_size, &b); read_sector = grub_divmod64 (read_sector, array->total_devs - n, &disknr); if (array->level >= 5) { grub_divmod64 (read_sector, array->total_devs, &p); if (! (array->layout & GRUB_RAID_LAYOUT_RIGHT_MASK)) p = array->total_devs - 1 - p; if (array->layout & GRUB_RAID_LAYOUT_SYMMETRIC_MASK) { disknr += p + n; } else { grub_uint32_t q; q = p + (n - 1); if (q >= array->total_devs) q -= array->total_devs; if (disknr >= p) disknr += n; else if (disknr >= q) disknr += q + 1; } if (disknr >= array->total_devs) disknr -= array->total_devs; } else p = array->total_devs - n; read_sector *= array->chunk_size; while (1) { grub_size_t read_size; int next_level; read_size = array->chunk_size - b; if (read_size > size) read_size = size; e = 0; if (array->device[disknr]) { /* Reset read error. */ if (grub_errno == GRUB_ERR_READ_ERROR) grub_errno = GRUB_ERR_NONE; err = grub_disk_read (array->device[disknr], read_sector + b, 0, read_size << GRUB_DISK_SECTOR_BITS, buf); if ((err) && (err != GRUB_ERR_READ_ERROR)) break; e++; } else err = GRUB_ERR_READ_ERROR; if (err) { if (array->nr_devs < array->total_devs - n + e) break; grub_errno = GRUB_ERR_NONE; if (array->level == 6) { err = ((grub_raid6_recover_func) ? (*grub_raid6_recover_func) (array, disknr, p, buf, read_sector + b, read_size) : grub_error (GRUB_ERR_BAD_DEVICE, "raid6rec is not loaded")); } else { err = ((grub_raid5_recover_func) ? (*grub_raid5_recover_func) (array, disknr, buf, read_sector + b, read_size) : grub_error (GRUB_ERR_BAD_DEVICE, "raid5rec is not loaded")); } if (err) break; } buf += read_size << GRUB_DISK_SECTOR_BITS; size -= read_size; if (! size) break; b = 0; disknr++; if (array->layout & GRUB_RAID_LAYOUT_SYMMETRIC_MASK) { if (disknr == array->total_devs) disknr = 0; next_level = (disknr == p); } else { if (disknr == p) disknr += n; next_level = (disknr >= array->total_devs); } if (next_level) { read_sector += array->chunk_size; if (array->level >= 5) { if (array->layout & GRUB_RAID_LAYOUT_RIGHT_MASK) p = (p == array->total_devs - 1) ? 0 : p + 1; else p = (p == 0) ? array->total_devs - 1 : p - 1; if (array->layout & GRUB_RAID_LAYOUT_SYMMETRIC_MASK) { disknr = p + n; if (disknr >= array->total_devs) disknr -= array->total_devs; } else { disknr -= array->total_devs; if (disknr == p) disknr += n; } } else disknr = 0; } } } break; } return err; } static grub_err_t grub_raid_write (grub_disk_t disk __attribute ((unused)), grub_disk_addr_t sector __attribute ((unused)), grub_size_t size __attribute ((unused)), const char *buf __attribute ((unused))) { return GRUB_ERR_NOT_IMPLEMENTED_YET; } static grub_err_t insert_array (grub_disk_t disk, struct grub_raid_array *new_array, const char *scanner_name) { struct grub_raid_array *array = 0, *p; /* See whether the device is part of an array we have already seen a device from. */ for (p = array_list; p != NULL; p = p->next) if ((p->uuid_len == new_array->uuid_len) && (! grub_memcmp (p->uuid, new_array->uuid, p->uuid_len))) { grub_free (new_array->uuid); array = p; /* Do some checks before adding the device to the array. */ /* FIXME: Check whether the update time of the superblocks are the same. */ if (array->total_devs == array->nr_devs) /* We found more members of the array than the array actually has according to its superblock. This shouldn't happen normally, but what is the sanest things to do in such a case? */ return grub_error (GRUB_ERR_BAD_NUMBER, "array->nr_devs > array->total_devs (%d)?!?", array->total_devs); if (array->device[new_array->index] != NULL) /* We found multiple devices with the same number. Again, this shouldn't happen.*/ return grub_error (GRUB_ERR_BAD_NUMBER, "Found two disks with the number %d?!?", new_array->number); if (new_array->disk_size < array->disk_size) array->disk_size = new_array->disk_size; break; } /* Add an array to the list if we didn't find any. */ if (!array) { array = grub_malloc (sizeof (*array)); if (!array) { grub_free (new_array->uuid); return grub_errno; } *array = *new_array; array->nr_devs = 0; grub_memset (&array->device, 0, sizeof (array->device)); /* Check whether we don't have multiple arrays with the same number. */ for (p = array_list; p != NULL; p = p->next) { if (p->number == array->number) break; } if (p) { /* The number is already in use, so we need to find an new number. */ int i = 0; while (1) { for (p = array_list; p != NULL; p = p->next) { if (p->number == i) break; } if (!p) { /* We found an unused number. */ array->number = i; break; } i++; } } array->name = grub_malloc (13); if (! array->name) { grub_free (array->uuid); grub_free (array); return grub_errno; } grub_sprintf (array->name, "md%d", array->number); grub_dprintf ("raid", "Found array %s (%s)\n", array->name, scanner_name); /* Add our new array to the list. */ array->next = array_list; array_list = array; } /* Add the device to the array. */ array->device[new_array->index] = disk; array->nr_devs++; return 0; } static grub_raid_t grub_raid_list; static void grub_raid_scan_device (int head_only) { auto int hook (const char *name); int hook (const char *name) { grub_disk_t disk; struct grub_raid_array array; struct grub_raid *p; grub_dprintf ("raid", "Scanning for RAID devices\n"); disk = grub_disk_open (name); if (!disk) return 0; if (disk->total_sectors == ULONG_MAX) { grub_disk_close (disk); return 0; } for (p = grub_raid_list; p; p = p->next) { if (! p->detect (disk, &array)) { if (! insert_array (disk, &array, p->name)) return 0; break; } /* This error usually means it's not raid, no need to display it. */ if (grub_errno != GRUB_ERR_OUT_OF_RANGE) grub_print_error (); grub_errno = GRUB_ERR_NONE; if (head_only) break; } grub_disk_close (disk); return 0; } grub_device_iterate (&hook); } static void free_array (void) { struct grub_raid_array *array; array = array_list; while (array) { struct grub_raid_array *p; int i; p = array; array = array->next; for (i = 0; i < GRUB_RAID_MAX_DEVICES; i++) if (p->device[i]) grub_disk_close (p->device[i]); grub_free (p->uuid); grub_free (p->name); grub_free (p); } array_list = 0; } void grub_raid_register (grub_raid_t raid) { raid->next = grub_raid_list; grub_raid_list = raid; grub_raid_scan_device (1); } void grub_raid_unregister (grub_raid_t raid) { grub_raid_t *p, q; for (p = &grub_raid_list, q = *p; q; p = &(q->next), q = q->next) if (q == raid) { *p = q->next; break; } } void grub_raid_rescan (void) { free_array (); grub_raid_scan_device (0); } static struct grub_disk_dev grub_raid_dev = { .name = "raid", .id = GRUB_DISK_DEVICE_RAID_ID, .iterate = grub_raid_iterate, .open = grub_raid_open, .close = grub_raid_close, .read = grub_raid_read, .write = grub_raid_write, #ifdef GRUB_UTIL .memberlist = grub_raid_memberlist, #endif .next = 0 }; GRUB_MOD_INIT(raid) { grub_disk_dev_register (&grub_raid_dev); } GRUB_MOD_FINI(raid) { grub_disk_dev_unregister (&grub_raid_dev); free_array (); }