/* * Copyright (C) 2014-2015 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #include "lib/misc/lib.h" #include "lib/metadata/metadata.h" #include "lib/locking/locking.h" #include "lib/misc/lvm-string.h" #include "lib/commands/toolcontext.h" #include "lib/display/display.h" #include "lib/metadata/segtype.h" #include "lib/activate/activate.h" #include "lib/config/defaults.h" #define DEFAULT_TAG_SIZE 4 /* bytes */ #define DEFAULT_MODE 'J' #define DEFAULT_INTERNAL_HASH "crc32c" #define DEFAULT_BLOCK_SIZE 512 #define ONE_MB_IN_BYTES 1048576 #define ONE_GB_IN_BYTES 1073741824 int lv_is_integrity_origin(const struct logical_volume *lv) { struct seg_list *sl; dm_list_iterate_items(sl, &lv->segs_using_this_lv) { if (!sl->seg || !sl->seg->lv || !sl->seg->origin) continue; if (lv_is_integrity(sl->seg->lv) && (sl->seg->origin == lv)) return 1; } return 0; } /* * Every 500M of data needs 4M of metadata. * (From trial and error testing.) * * plus some initial space for journals. * (again from trial and error testing.) */ static uint64_t _lv_size_bytes_to_integrity_meta_bytes(uint64_t lv_size_bytes) { uint64_t meta_bytes; uint64_t initial_bytes; /* Every 500M of data needs 4M of metadata. */ meta_bytes = ((lv_size_bytes / (500 * ONE_MB_IN_BYTES)) + 1) * (4 * ONE_MB_IN_BYTES); /* * initial space used for journals * lv_size <= 512M -> 4M * lv_size <= 1G -> 8M * lv_size <= 4G -> 32M * lv_size > 4G -> 64M */ if (lv_size_bytes <= (512 * ONE_MB_IN_BYTES)) initial_bytes = 4 * ONE_MB_IN_BYTES; else if (lv_size_bytes <= ONE_GB_IN_BYTES) initial_bytes = 8 * ONE_MB_IN_BYTES; else if (lv_size_bytes <= (4ULL * ONE_GB_IN_BYTES)) initial_bytes = 32 * ONE_MB_IN_BYTES; else if (lv_size_bytes > (4ULL * ONE_GB_IN_BYTES)) initial_bytes = 64 * ONE_MB_IN_BYTES; return meta_bytes + initial_bytes; } /* * The user wants external metadata, but did not specify an existing * LV to hold metadata, so create an LV for metadata. */ static int _lv_create_integrity_metadata(struct cmd_context *cmd, struct volume_group *vg, struct lvcreate_params *lp, struct logical_volume **meta_lv) { char metaname[NAME_LEN] = { 0 }; uint64_t lv_size_bytes, meta_bytes, meta_sectors; struct logical_volume *lv; struct lvcreate_params lp_meta = { .activate = CHANGE_AN, .alloc = ALLOC_INHERIT, .major = -1, .minor = -1, .permission = LVM_READ | LVM_WRITE, .pvh = &vg->pvs, .read_ahead = DM_READ_AHEAD_NONE, .stripes = 1, .vg_name = vg->name, .zero = 0, .wipe_signatures = 0, .suppress_zero_warn = 1, }; if (lp->lv_name && dm_snprintf(metaname, NAME_LEN, "%s_imeta", lp->lv_name) < 0) { log_error("Failed to create metadata LV name."); return 0; } lp_meta.lv_name = metaname; lp_meta.pvh = lp->pvh; lv_size_bytes = (uint64_t)lp->extents * (uint64_t)vg->extent_size * 512; meta_bytes = _lv_size_bytes_to_integrity_meta_bytes(lv_size_bytes); meta_sectors = meta_bytes / 512; lp_meta.extents = meta_sectors / vg->extent_size; log_print_unless_silent("Creating integrity metadata LV %s with size %s.", metaname, display_size(cmd, meta_sectors)); dm_list_init(&lp_meta.tags); if (!(lp_meta.segtype = get_segtype_from_string(vg->cmd, SEG_TYPE_NAME_STRIPED))) return_0; if (!(lv = lv_create_single(vg, &lp_meta))) { log_error("Failed to create integrity metadata LV"); return 0; } if (dm_list_size(&lv->segments) > 1) { log_error("Integrity metadata uses more than one segment."); return 0; } *meta_lv = lv; return 1; } int lv_extend_integrity_in_raid(struct logical_volume *lv, struct dm_list *pvh) { struct cmd_context *cmd = lv->vg->cmd; struct volume_group *vg = lv->vg; const struct segment_type *segtype; struct lv_segment *seg_top, *seg_image; struct logical_volume *lv_image; struct logical_volume *lv_iorig; struct logical_volume *lv_imeta; struct dm_list allocatable_pvs; struct dm_list *use_pvh; uint64_t lv_size_bytes, meta_bytes, meta_sectors, prev_meta_sectors; uint32_t meta_extents, prev_meta_extents; uint32_t area_count, s; if (!lv_is_raid(lv)) return_0; seg_top = first_seg(lv); if (!(segtype = get_segtype_from_string(cmd, SEG_TYPE_NAME_STRIPED))) return_0; area_count = seg_top->area_count; for (s = 0; s < area_count; s++) { lv_image = seg_lv(seg_top, s); seg_image = first_seg(lv_image); if (!(lv_imeta = seg_image->integrity_meta_dev)) { log_error("LV %s segment has no integrity metadata device.", display_lvname(lv)); return 0; } if (!(lv_iorig = seg_lv(seg_image, 0))) { log_error("LV %s integrity segment has no origin", display_lvname(lv)); return 0; } lv_size_bytes = lv_iorig->size * 512; meta_bytes = _lv_size_bytes_to_integrity_meta_bytes(lv_size_bytes); meta_sectors = meta_bytes / 512; meta_extents = meta_sectors / vg->extent_size; prev_meta_sectors = lv_imeta->size; prev_meta_extents = prev_meta_sectors / vg->extent_size; if (meta_extents <= prev_meta_extents) { log_debug("extend not needed for imeta LV %s", lv_imeta->name); continue; } /* * We only allow lv_imeta to exist on a single PV (for now), * so the allocatable_pvs is the one PV currently used by * lv_imeta. */ dm_list_init(&allocatable_pvs); if (!get_pv_list_for_lv(cmd->mem, lv_imeta, &allocatable_pvs)) { log_error("Failed to build list of PVs for extending %s.", display_lvname(lv_imeta)); return 0; } use_pvh = &allocatable_pvs; if (!lv_extend(lv_imeta, segtype, 1, 0, 0, 0, meta_extents - prev_meta_extents, use_pvh, lv_imeta->alloc, 0)) { log_error("Failed to extend integrity metadata LV %s", lv_imeta->name); return 0; } } return 1; } int lv_remove_integrity_from_raid(struct logical_volume *lv) { struct logical_volume *iorig_lvs[DEFAULT_RAID_MAX_IMAGES]; struct logical_volume *imeta_lvs[DEFAULT_RAID_MAX_IMAGES]; struct cmd_context *cmd = lv->vg->cmd; struct volume_group *vg = lv->vg; struct lv_segment *seg_top, *seg_image; struct logical_volume *lv_image; struct logical_volume *lv_iorig; struct logical_volume *lv_imeta; uint32_t area_count, s; int is_active = lv_is_active(lv); seg_top = first_seg(lv); if (!seg_is_raid1(seg_top) && !seg_is_raid4(seg_top) && !seg_is_any_raid5(seg_top) && !seg_is_any_raid6(seg_top) && !seg_is_any_raid10(seg_top)) { log_error("LV %s segment is unsupported raid for integrity.", display_lvname(lv)); return 0; } area_count = seg_top->area_count; for (s = 0; s < area_count; s++) { lv_image = seg_lv(seg_top, s); seg_image = first_seg(lv_image); if (!(lv_imeta = seg_image->integrity_meta_dev)) { log_error("LV %s segment has no integrity metadata device.", display_lvname(lv)); return 0; } if (!(lv_iorig = seg_lv(seg_image, 0))) { log_error("LV %s integrity segment has no origin", display_lvname(lv)); return 0; } if (!remove_seg_from_segs_using_this_lv(seg_image->integrity_meta_dev, seg_image)) return_0; iorig_lvs[s] = lv_iorig; imeta_lvs[s] = lv_imeta; lv_image->status &= ~INTEGRITY; seg_image->integrity_meta_dev = NULL; seg_image->integrity_data_sectors = 0; memset(&seg_image->integrity_settings, 0, sizeof(seg_image->integrity_settings)); if (!remove_layer_from_lv(lv_image, lv_iorig)) return_0; } if (is_active) { /* vg_write(), suspend_lv(), vg_commit(), resume_lv() */ if (!lv_update_and_reload(lv)) { log_error("Failed to update and reload LV after integrity remove."); return 0; } } for (s = 0; s < area_count; s++) { lv_iorig = iorig_lvs[s]; lv_imeta = imeta_lvs[s]; if (is_active) { if (!deactivate_lv(cmd, lv_iorig)) log_error("Failed to deactivate unused iorig LV %s.", lv_iorig->name); if (!deactivate_lv(cmd, lv_imeta)) log_error("Failed to deactivate unused imeta LV %s.", lv_imeta->name); } lv_imeta->status &= ~INTEGRITY_METADATA; lv_set_visible(lv_imeta); if (!lv_remove(lv_iorig)) log_error("Failed to remove unused iorig LV %s.", lv_iorig->name); if (!lv_remove(lv_imeta)) log_error("Failed to remove unused imeta LV %s.", lv_imeta->name); } if (!vg_write(vg) || !vg_commit(vg)) return_0; return 1; } int integrity_mode_set(const char *mode, struct integrity_settings *settings) { if (!mode) settings->mode[0] = DEFAULT_MODE; else if (!strcmp(mode, "bitmap") || !strcmp(mode, "B")) settings->mode[0] = 'B'; else if (!strcmp(mode, "journal") || !strcmp(mode, "J")) settings->mode[0] = 'J'; else { log_error("Invalid raid integrity mode (use \"bitmap\" or \"journal\")"); return 0; } return 1; } static int _set_integrity_block_size(struct cmd_context *cmd, struct logical_volume *lv, int is_active, struct integrity_settings *settings, int lbs_4k, int lbs_512, int pbs_4k, int pbs_512) { char pathname[PATH_MAX]; uint32_t fs_block_size = 0; int rv; if (lbs_4k && lbs_512) { log_error("Integrity requires consistent logical block size for LV devices."); goto bad; } if (settings->block_size && (settings->block_size != 512 && settings->block_size != 1024 && settings->block_size != 2048 && settings->block_size != 4096)) { log_error("Invalid integrity block size, possible values are 512, 1024, 2048, 4096"); goto bad; } if (lbs_4k && settings->block_size && (settings->block_size < 4096)) { log_error("Integrity block size %u not allowed with device logical block size 4096.", settings->block_size); goto bad; } if (!strcmp(cmd->name, "lvcreate")) { if (lbs_4k) { settings->block_size = 4096; } else if (lbs_512 && pbs_4k && !pbs_512) { settings->block_size = 4096; } else if (lbs_512) { if (!settings->block_size) settings->block_size = 512; } else if (!lbs_4k && !lbs_512) { if (!settings->block_size) settings->block_size = 512; log_print("Using integrity block size %u with unknown device logical block size.", settings->block_size); } else { goto_bad; } } else if (!strcmp(cmd->name, "lvconvert")) { if (dm_snprintf(pathname, sizeof(pathname), "%s%s/%s", cmd->dev_dir, lv->vg->name, lv->name) < 0) { log_error("Path name too long to get LV block size %s", display_lvname(lv)); goto bad; } /* * get_fs_block_size() returns the libblkid BLOCK_SIZE value, * where libblkid has fs-specific code to set BLOCK_SIZE to the * value we need here. * * The term "block size" here may not equate directly to what the fs * calls the block size, e.g. xfs calls this the sector size (and * something different the block size); while ext4 does call this * value the block size, but it's possible values are not the same * as xfs's, and do not seem to relate directly to the device LBS. */ rv = get_fs_block_size(pathname, &fs_block_size); if (!rv || !fs_block_size) { int use_bs; if (lbs_4k && pbs_4k) { use_bs = 4096; } else if (lbs_512 && pbs_512) { use_bs = 512; } else if (lbs_512 && pbs_4k) { if (settings->block_size == 4096) use_bs = 4096; else use_bs = 512; } else { use_bs = 512; } if (settings->block_size && (settings->block_size != use_bs)) { log_error("Cannot use integrity block size %u with unknown file system block size, logical block size %u, physical block size %u.", settings->block_size, lbs_4k ? 4096 : 512, pbs_4k ? 4096 : 512); goto bad; } settings->block_size = use_bs; log_print("Using integrity block size %u for unknown file system block size, logical block size %u, physical block size %u.", settings->block_size, lbs_4k ? 4096 : 512, pbs_4k ? 4096 : 512); goto out; } if (!settings->block_size) { if (is_active && lbs_512) { /* increasing the lbs from 512 to 4k under an active LV could cause problems for an application that expects a given io size/alignment is possible. */ settings->block_size = 512; if (fs_block_size > 512) log_print("Limiting integrity block size to 512 because the LV is active."); } else if (fs_block_size <= 4096) settings->block_size = fs_block_size; else settings->block_size = 4096; /* dm-integrity max is 4096 */ log_print("Using integrity block size %u for file system block size %u.", settings->block_size, fs_block_size); } else { /* let user specify integrity block size that is less than fs block size */ if (settings->block_size > fs_block_size) { log_error("Integrity block size %u cannot be larger than file system block size %u.", settings->block_size, fs_block_size); goto bad; } log_print("Using integrity block size %u for file system block size %u.", settings->block_size, fs_block_size); } } out: return 1; bad: return 0; } /* * Add integrity to each raid image. * * for each rimage_N: * . create and allocate a new linear LV rimage_N_imeta * . move the segments from rimage_N to a new rimage_N_iorig * . add an integrity segment to rimage_N with * origin=rimage_N_iorig, meta_dev=rimage_N_imeta * * Before: * rimage_0 * segment1: striped: pv0:A * rimage_1 * segment1: striped: pv1:B * * After: * rimage_0 * segment1: integrity: rimage_0_iorig, rimage_0_imeta * rimage_1 * segment1: integrity: rimage_1_iorig, rimage_1_imeta * rimage_0_iorig * segment1: striped: pv0:A * rimage_1_iorig * segment1: striped: pv1:B * rimage_0_imeta * segment1: striped: pv2:A * rimage_1_imeta * segment1: striped: pv2:B * */ int lv_add_integrity_to_raid(struct logical_volume *lv, struct integrity_settings *settings, struct dm_list *pvh, struct logical_volume *lv_imeta_0) { char imeta_name[NAME_LEN]; char *imeta_name_dup; struct lvcreate_params lp; struct dm_list allocatable_pvs; struct logical_volume *imeta_lvs[DEFAULT_RAID_MAX_IMAGES]; struct cmd_context *cmd = lv->vg->cmd; struct volume_group *vg = lv->vg; struct logical_volume *lv_image, *lv_imeta, *lv_iorig; struct lv_segment *seg_top, *seg_image; struct pv_list *pvl; const struct segment_type *segtype; struct integrity_settings *set = NULL; struct dm_list *use_pvh = NULL; uint32_t area_count, s; uint32_t revert_meta_lvs = 0; int lbs_4k = 0, lbs_512 = 0, lbs_unknown = 0; int pbs_4k = 0, pbs_512 = 0, pbs_unknown = 0; int is_active; memset(imeta_lvs, 0, sizeof(imeta_lvs)); is_active = lv_is_active(lv); if (dm_list_size(&lv->segments) != 1) return_0; if (!dm_list_empty(&lv->segs_using_this_lv)) { log_error("Integrity can only be added to top level raid LV."); return 0; } if (lv_is_origin(lv)) { log_error("Integrity cannot be added to snapshot origins."); return 0; } seg_top = first_seg(lv); area_count = seg_top->area_count; if (!seg_is_raid1(seg_top) && !seg_is_raid4(seg_top) && !seg_is_any_raid5(seg_top) && !seg_is_any_raid6(seg_top) && !seg_is_any_raid10(seg_top)) { log_error("Integrity can only be added to raid1,4,5,6,10."); return 0; } /* * For each rimage, create an _imeta LV for integrity metadata. * Each needs to be zeroed. */ for (s = 0; s < area_count; s++) { struct logical_volume *meta_lv; struct wipe_params wipe = { .do_zero = 1 }; if (s >= DEFAULT_RAID_MAX_IMAGES) goto_bad; lv_image = seg_lv(seg_top, s); /* * This function is used to add integrity to new images added * to the raid, in which case old images will already be * integrity. */ if (seg_is_integrity(first_seg(lv_image))) continue; if (!seg_is_striped(first_seg(lv_image))) { log_error("raid image must be linear to add integrity"); goto bad; } /* * Use an existing lv_imeta from previous linear+integrity LV. * FIXME: is it guaranteed that lv_image_0 is the existing? */ if (!s && lv_imeta_0) { if (dm_snprintf(imeta_name, sizeof(imeta_name), "%s_imeta", lv_image->name) > 0) { if ((imeta_name_dup = dm_pool_strdup(vg->vgmem, imeta_name))) lv_imeta_0->name = imeta_name_dup; } imeta_lvs[0] = lv_imeta_0; continue; } dm_list_init(&allocatable_pvs); if (!get_pv_list_for_lv(cmd->mem, lv_image, &allocatable_pvs)) { log_error("Failed to build list of PVs for %s.", display_lvname(lv_image)); goto bad; } dm_list_iterate_items(pvl, &allocatable_pvs) { unsigned int pbs = 0; unsigned int lbs = 0; if (!dev_get_direct_block_sizes(pvl->pv->dev, &pbs, &lbs)) { lbs_unknown++; pbs_unknown++; continue; } if (lbs == 4096) lbs_4k++; else if (lbs == 512) lbs_512++; else lbs_unknown++; if (pbs == 4096) pbs_4k++; else if (pbs == 512) pbs_512++; else pbs_unknown++; } use_pvh = &allocatable_pvs; /* * allocate a new linear LV NAME_rimage_N_imeta */ memset(&lp, 0, sizeof(lp)); lp.lv_name = lv_image->name; lp.pvh = use_pvh; lp.extents = lv_image->size / vg->extent_size; if (!_lv_create_integrity_metadata(cmd, vg, &lp, &meta_lv)) goto_bad; revert_meta_lvs++; /* Used below to set up the new integrity segment. */ imeta_lvs[s] = meta_lv; /* * dm-integrity requires the metadata LV header to be zeroed. */ if (!activate_lv(cmd, meta_lv)) { log_error("Failed to activate LV %s to zero", display_lvname(meta_lv)); goto bad; } if (!wipe_lv(meta_lv, wipe)) { log_error("Failed to zero LV for integrity metadata %s", display_lvname(meta_lv)); if (deactivate_lv(cmd, meta_lv)) log_error("Failed to deactivate LV %s after zero", display_lvname(meta_lv)); goto bad; } if (!deactivate_lv(cmd, meta_lv)) { log_error("Failed to deactivate LV %s after zero", display_lvname(meta_lv)); goto bad; } } if (!is_active) { /* checking block size of fs on the lv requires the lv to be active */ if (!activate_lv(cmd, lv)) { log_error("Failed to activate LV to check block size %s", display_lvname(lv)); goto bad; } if (!sync_local_dev_names(cmd)) stack; } /* * Set settings->block_size which will be copied to segment settings below. * integrity block size chosen based on device logical block size and * file system block size. */ if (!_set_integrity_block_size(cmd, lv, is_active, settings, lbs_4k, lbs_512, pbs_4k, pbs_512)) { if (!is_active && !deactivate_lv(cmd, lv)) stack; goto_bad; } if (!is_active) { if (!deactivate_lv(cmd, lv)) { log_error("Failed to deactivate LV after checking block size %s", display_lvname(lv)); goto bad; } } /* * For each rimage, move its segments to a new rimage_iorig and give * the rimage a new integrity segment. */ for (s = 0; s < area_count; s++) { lv_image = seg_lv(seg_top, s); /* Not adding integrity to this image. */ if (!imeta_lvs[s]) continue; if (!(segtype = get_segtype_from_string(cmd, SEG_TYPE_NAME_INTEGRITY))) goto_bad; log_debug("Adding integrity to raid image %s", lv_image->name); /* * "lv_iorig" is a new LV with new id, but with the segments * from "lv_image". "lv_image" keeps the existing name and id, * but gets a new integrity segment, in place of the segments * that were moved to lv_iorig. */ if (!(lv_iorig = insert_layer_for_lv(cmd, lv_image, INTEGRITY, "_iorig"))) goto_bad; lv_image->status |= INTEGRITY; /* * Set up the new first segment of lv_image as integrity. */ seg_image = first_seg(lv_image); seg_image->segtype = segtype; lv_imeta = imeta_lvs[s]; lv_imeta->status |= INTEGRITY_METADATA; lv_set_hidden(lv_imeta); seg_image->integrity_data_sectors = lv_image->size; seg_image->integrity_meta_dev = lv_imeta; seg_image->integrity_recalculate = 1; memcpy(&seg_image->integrity_settings, settings, sizeof(struct integrity_settings)); set = &seg_image->integrity_settings; if (!set->mode[0]) set->mode[0] = DEFAULT_MODE; if (!set->tag_size) set->tag_size = DEFAULT_TAG_SIZE; if (!set->block_size) set->block_size = DEFAULT_BLOCK_SIZE; if (!set->internal_hash) set->internal_hash = DEFAULT_INTERNAL_HASH; } if (is_active) { log_debug("Writing VG and updating LV with new integrity LV %s", lv->name); /* vg_write(), suspend_lv(), vg_commit(), resume_lv() */ if (!lv_update_and_reload(lv)) { log_error("LV update and reload failed"); goto bad; } revert_meta_lvs = 0; } else { log_debug("Writing VG with new integrity LV %s", lv->name); if (!vg_write(vg) || !vg_commit(vg)) goto_bad; revert_meta_lvs = 0; /* * This first activation includes "recalculate" which starts the * kernel's recalculating (initialization) process. */ log_debug("Activating to start integrity initialization for LV %s", lv->name); if (!activate_lv(cmd, lv)) { log_error("Failed to activate integrity LV to initialize."); goto bad; } } /* * Now that the device is being initialized, update the VG to clear * integrity_recalculate so that subsequent activations will not * include "recalculate" and restart initialization. */ log_debug("Writing VG with initialized integrity LV %s", lv->name); for (s = 0; s < area_count; s++) { lv_image = seg_lv(seg_top, s); seg_image = first_seg(lv_image); seg_image->integrity_recalculate = 0; } if (!vg_write(vg) || !vg_commit(vg)) goto_bad; return 1; bad: log_error("Failed to add integrity."); if (revert_meta_lvs) { for (s = 0; s < DEFAULT_RAID_MAX_IMAGES; s++) { if (!imeta_lvs[s]) continue; if (!lv_remove(imeta_lvs[s])) log_error("New integrity metadata LV may require manual removal."); } } if (!vg_write(vg) || !vg_commit(vg)) log_error("New integrity metadata LV may require manual removal."); return 0; } /* * This should rarely if ever be used. A command that adds integrity * to an LV will activate and then clear the flag. If it fails before * clearing the flag, then this function will be used by a subsequent * activation to clear the flag. */ void lv_clear_integrity_recalculate_metadata(struct logical_volume *lv) { struct volume_group *vg = lv->vg; struct logical_volume *lv_image; struct lv_segment *seg, *seg_image; uint32_t s; if (!lv_is_raid(lv) && !lv_is_integrity(lv)) { log_error("Invalid LV type for clearing integrity"); return; } seg = first_seg(lv); if (seg_is_raid(seg)) { for (s = 0; s < seg->area_count; s++) { lv_image = seg_lv(seg, s); seg_image = first_seg(lv_image); seg_image->integrity_recalculate = 0; } } else if (seg_is_integrity(seg)) { seg->integrity_recalculate = 0; } if (!vg_write(vg) || !vg_commit(vg)) { log_warn("WARNING: failed to clear integrity recalculate flag for %s", display_lvname(lv)); } } int lv_has_integrity_recalculate_metadata(struct logical_volume *lv) { struct logical_volume *lv_image; struct lv_segment *seg, *seg_image; uint32_t s; int ret = 0; if (!lv_is_raid(lv) && !lv_is_integrity(lv)) return 0; seg = first_seg(lv); if (seg_is_raid(seg)) { for (s = 0; s < seg->area_count; s++) { lv_image = seg_lv(seg, s); seg_image = first_seg(lv_image); if (!seg_is_integrity(seg_image)) continue; if (seg_image->integrity_recalculate) ret = 1; } } else if (seg_is_integrity(seg)) { ret = seg->integrity_recalculate; } return ret; } int lv_raid_has_integrity(struct logical_volume *lv) { struct logical_volume *lv_image; struct lv_segment *seg, *seg_image; uint32_t s; if (!lv_is_raid(lv)) return 0; seg = first_seg(lv); for (s = 0; s < seg->area_count; s++) { lv_image = seg_lv(seg, s); seg_image = first_seg(lv_image); if (seg_is_integrity(seg_image)) return 1; } return 0; } int lv_get_raid_integrity_settings(struct logical_volume *lv, struct integrity_settings **isettings) { struct logical_volume *lv_image; struct lv_segment *seg, *seg_image; uint32_t s; if (!lv_is_raid(lv)) return_0; seg = first_seg(lv); for (s = 0; s < seg->area_count; s++) { lv_image = seg_lv(seg, s); seg_image = first_seg(lv_image); if (seg_is_integrity(seg_image)) { *isettings = &seg_image->integrity_settings; return 1; } } return 0; } int lv_raid_integrity_total_mismatches(struct cmd_context *cmd, const struct logical_volume *lv, uint64_t *mismatches) { struct logical_volume *lv_image; struct lv_segment *seg, *seg_image; uint32_t s; uint64_t mismatches_image; uint64_t total = 0; int errors = 0; if (!lv_is_raid(lv)) return 0; seg = first_seg(lv); for (s = 0; s < seg->area_count; s++) { lv_image = seg_lv(seg, s); seg_image = first_seg(lv_image); if (!seg_is_integrity(seg_image)) continue; mismatches_image = 0; if (!lv_integrity_mismatches(cmd, lv_image, &mismatches_image)) errors++; total += mismatches_image; } *mismatches = total; if (errors) return 0; return 1; } int lv_integrity_mismatches(struct cmd_context *cmd, const struct logical_volume *lv, uint64_t *mismatches) { struct lv_with_info_and_seg_status status; if (lv_is_raid(lv) && lv_raid_has_integrity((struct logical_volume *)lv)) return lv_raid_integrity_total_mismatches(cmd, lv, mismatches); if (!lv_is_integrity(lv)) return_0; memset(&status, 0, sizeof(status)); status.seg_status.type = SEG_STATUS_NONE; status.seg_status.seg = first_seg(lv); /* FIXME: why reporter_pool? */ if (!(status.seg_status.mem = dm_pool_create("reporter_pool", 1024))) { log_error("Failed to get mem for LV status."); return 0; } if (!lv_info_with_seg_status(cmd, first_seg(lv), &status, 1, 1)) { log_error("Failed to get device mapper status for %s", display_lvname(lv)); goto fail; } if (!status.info.exists) goto fail; if (status.seg_status.type != SEG_STATUS_INTEGRITY) { log_error("Invalid device mapper status type (%d) for %s", (uint32_t)status.seg_status.type, display_lvname(lv)); goto fail; } *mismatches = status.seg_status.integrity->number_of_mismatches; dm_pool_destroy(status.seg_status.mem); return 1; fail: dm_pool_destroy(status.seg_status.mem); return 0; }