/* * Copyright (C) 2004 Luca Berra * Copyright (C) 2004-2008 Red Hat, Inc. All rights reserved. * * This file is part of LVM2. * * This copyrighted material is made available to anyone wishing to use, * modify, copy, or redistribute it subject to the terms and conditions * of the GNU Lesser General Public License v.2.1. * * You should have received a copy of the GNU Lesser 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 */ #include "lib.h" #include "metadata.h" #include "xlate.h" #include "filter.h" #ifdef linux /* Lifted from because of difficulty including it */ #define MD_SB_MAGIC 0xa92b4efc #define MD_RESERVED_BYTES (64 * 1024ULL) #define MD_RESERVED_SECTORS (MD_RESERVED_BYTES / 512) #define MD_NEW_SIZE_SECTORS(x) ((x & ~(MD_RESERVED_SECTORS - 1)) \ - MD_RESERVED_SECTORS) static int _dev_has_md_magic(struct device *dev, uint64_t sb_offset) { uint32_t md_magic; /* Version 1 is little endian; version 0.90.0 is machine endian */ if (dev_read(dev, sb_offset, sizeof(uint32_t), &md_magic) && ((md_magic == xlate32(MD_SB_MAGIC)) || (md_magic == MD_SB_MAGIC))) return 1; return 0; } /* * Calculate the position of the superblock. * It is always aligned to a 4K boundary and * depending on minor_version, it can be: * 0: At least 8K, but less than 12K, from end of device * 1: At start of device * 2: 4K from start of device. */ typedef enum { MD_MINOR_VERSION_MIN, MD_MINOR_V0 = MD_MINOR_VERSION_MIN, MD_MINOR_V1, MD_MINOR_V2, MD_MINOR_VERSION_MAX = MD_MINOR_V2 } md_minor_version_t; static uint64_t _v1_sb_offset(uint64_t size, md_minor_version_t minor_version) { uint64_t uninitialized_var(sb_offset); switch(minor_version) { case MD_MINOR_V0: sb_offset = (size - 8 * 2) & ~(4 * 2 - 1ULL); break; case MD_MINOR_V1: sb_offset = 0; break; case MD_MINOR_V2: sb_offset = 4 * 2; break; } sb_offset <<= SECTOR_SHIFT; return sb_offset; } /* * Returns -1 on error */ int dev_is_md(struct device *dev, uint64_t *sb) { int ret = 1; md_minor_version_t minor; uint64_t size, sb_offset; if (!dev_get_size(dev, &size)) { stack; return -1; } if (size < MD_RESERVED_SECTORS * 2) return 0; if (!dev_open(dev)) { stack; return -1; } /* Check if it is an md component device. */ /* Version 0.90.0 */ sb_offset = MD_NEW_SIZE_SECTORS(size) << SECTOR_SHIFT; if (_dev_has_md_magic(dev, sb_offset)) goto out; minor = MD_MINOR_VERSION_MIN; /* Version 1, try v1.0 -> v1.2 */ do { sb_offset = _v1_sb_offset(size, minor); if (_dev_has_md_magic(dev, sb_offset)) goto out; } while (++minor <= MD_MINOR_VERSION_MAX); ret = 0; out: if (!dev_close(dev)) stack; if (ret && sb) *sb = sb_offset; return ret; } static int _md_sysfs_attribute_snprintf(char *path, size_t size, const char *sysfs_dir, struct device *blkdev, const char *attribute) { struct stat info; dev_t dev = blkdev->dev; int ret = -1; if (!sysfs_dir || !*sysfs_dir) return ret; if (MAJOR(dev) == blkext_major()) { /* lookup parent MD device from blkext partition */ if (!get_primary_dev(sysfs_dir, blkdev, &dev)) return ret; } if (MAJOR(dev) != md_major()) return ret; ret = dm_snprintf(path, size, "%s/dev/block/%d:%d/md/%s", sysfs_dir, (int)MAJOR(dev), (int)MINOR(dev), attribute); if (ret < 0) { log_error("dm_snprintf md %s failed", attribute); return ret; } if (stat(path, &info) == -1) { if (errno != ENOENT) { log_sys_error("stat", path); return ret; } /* old sysfs structure */ ret = dm_snprintf(path, size, "%s/block/md%d/md/%s", sysfs_dir, (int)MINOR(dev), attribute); if (ret < 0) { log_error("dm_snprintf old md %s failed", attribute); return ret; } } return ret; } static int _md_sysfs_attribute_scanf(const char *sysfs_dir, struct device *dev, const char *attribute_name, const char *attribute_fmt, void *attribute_value) { char path[PATH_MAX+1], buffer[64]; FILE *fp; int ret = 0; if (_md_sysfs_attribute_snprintf(path, PATH_MAX, sysfs_dir, dev, attribute_name) < 0) return ret; if (!(fp = fopen(path, "r"))) { log_sys_error("fopen", path); return ret; } if (!fgets(buffer, sizeof(buffer), fp)) { log_sys_error("fgets", path); goto out; } if ((ret = sscanf(buffer, attribute_fmt, attribute_value)) != 1) { log_error("%s sysfs attr %s not in expected format: %s", dev_name(dev), attribute_name, buffer); goto out; } out: if (fclose(fp)) log_sys_error("fclose", path); return ret; } /* * Retrieve chunk size from md device using sysfs. */ static unsigned long dev_md_chunk_size(const char *sysfs_dir, struct device *dev) { const char *attribute = "chunk_size"; unsigned long chunk_size_bytes = 0UL; if (_md_sysfs_attribute_scanf(sysfs_dir, dev, attribute, "%lu", &chunk_size_bytes) != 1) return 0; log_very_verbose("Device %s %s is %lu bytes.", dev_name(dev), attribute, chunk_size_bytes); return chunk_size_bytes >> SECTOR_SHIFT; } /* * Retrieve level from md device using sysfs. */ static int dev_md_level(const char *sysfs_dir, struct device *dev) { const char *attribute = "level"; int level = -1; if (_md_sysfs_attribute_scanf(sysfs_dir, dev, attribute, "raid%d", &level) != 1) return -1; log_very_verbose("Device %s %s is raid%d.", dev_name(dev), attribute, level); return level; } /* * Retrieve raid_disks from md device using sysfs. */ static int dev_md_raid_disks(const char *sysfs_dir, struct device *dev) { const char *attribute = "raid_disks"; int raid_disks = 0; if (_md_sysfs_attribute_scanf(sysfs_dir, dev, attribute, "%d", &raid_disks) != 1) return 0; log_very_verbose("Device %s %s is %d.", dev_name(dev), attribute, raid_disks); return raid_disks; } /* * Calculate stripe width of md device using its sysfs files. */ unsigned long dev_md_stripe_width(const char *sysfs_dir, struct device *dev) { unsigned long chunk_size_sectors = 0UL; unsigned long stripe_width_sectors = 0UL; int level, raid_disks, data_disks; chunk_size_sectors = dev_md_chunk_size(sysfs_dir, dev); if (!chunk_size_sectors) return 0; level = dev_md_level(sysfs_dir, dev); if (level < 0) return 0; raid_disks = dev_md_raid_disks(sysfs_dir, dev); if (!raid_disks) return 0; /* The raid level governs the number of data disks. */ switch (level) { case 0: /* striped md does not have any parity disks */ data_disks = raid_disks; break; case 1: case 10: /* mirrored md effectively has 1 data disk */ data_disks = 1; break; case 4: case 5: /* both raid 4 and 5 have a single parity disk */ data_disks = raid_disks - 1; break; case 6: /* raid 6 has 2 parity disks */ data_disks = raid_disks - 2; break; default: log_error("Device %s has an unknown md raid level: %d", dev_name(dev), level); return 0; } stripe_width_sectors = chunk_size_sectors * data_disks; log_very_verbose("Device %s stripe-width is %lu bytes.", dev_name(dev), stripe_width_sectors << SECTOR_SHIFT); return stripe_width_sectors; } #else int dev_is_md(struct device *dev __attribute__((unused)), uint64_t *sb __attribute__((unused))) { return 0; } unsigned long dev_md_stripe_width(const char *sysfs_dir __attribute__((unused)), struct device *dev __attribute__((unused))) { return 0UL; } #endif