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lvm2/lib/metadata/pv.c

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/*
* Copyright (C) 2001-2004 Sistina Software, Inc. All rights reserved.
* Copyright (C) 2004-2010 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.h"
#include "metadata.h"
#include "lvmcache.h"
/*
* FIXME: Check for valid handle before dereferencing field or log error?
*/
#define pv_field(handle, field) ((handle)->field)
char *pv_fmt_dup(const struct physical_volume *pv)
{
if (!pv->fmt)
return NULL;
return dm_pool_strdup(pv->vg->vgmem, pv->fmt->name);
}
char *pv_name_dup(struct dm_pool *mem, const struct physical_volume *pv)
{
return dm_pool_strdup(mem ? mem : pv->vg->vgmem, dev_name(pv->dev));
}
/*
* Gets/Sets for external LVM library
*/
struct id pv_id(const struct physical_volume *pv)
{
return pv_field(pv, id);
}
char *pv_uuid_dup(struct dm_pool *mem, const struct physical_volume *pv)
{
return id_format_and_copy(mem ? mem : pv->vg->vgmem, &pv->id);
}
char *pv_tags_dup(const struct physical_volume *pv)
{
return tags_format_and_copy(pv->vg->vgmem, &pv->tags);
}
const struct format_type *pv_format_type(const struct physical_volume *pv)
{
return pv_field(pv, fmt);
}
struct id pv_vgid(const struct physical_volume *pv)
{
return pv_field(pv, vgid);
}
struct device *pv_dev(const struct physical_volume *pv)
{
return pv_field(pv, dev);
}
const char *pv_vg_name(const struct physical_volume *pv)
{
/* Avoid exposing internal orphan names to users */
return (!is_orphan(pv)) ? pv_field(pv, vg_name) : "";
}
const char *pv_dev_name(const struct physical_volume *pv)
{
return dev_name(pv_dev(pv));
}
uint64_t pv_size(const struct physical_volume *pv)
{
return pv_field(pv, size);
}
uint64_t pv_dev_size(const struct physical_volume *pv)
{
uint64_t size;
if (!dev_get_size(pv->dev, &size))
size = 0;
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return size;
}
uint64_t pv_size_field(const struct physical_volume *pv)
{
uint64_t size;
if (!pv->pe_count)
size = pv->size;
else
size = (uint64_t) pv->pe_count * pv->pe_size;
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return size;
}
uint64_t pv_free(const struct physical_volume *pv)
{
uint64_t freespace;
if (!pv->vg || is_orphan_vg(pv->vg->name))
freespace = pv->size;
else
freespace = (uint64_t)
(pv->pe_count - pv->pe_alloc_count) * pv->pe_size;
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return freespace;
}
uint64_t pv_status(const struct physical_volume *pv)
{
return pv_field(pv, status);
}
uint32_t pv_pe_size(const struct physical_volume *pv)
{
return pv_field(pv, pe_size);
}
uint64_t pv_ba_start(const struct physical_volume *pv)
{
return pv_field(pv, ba_start);
}
uint64_t pv_ba_size(const struct physical_volume *pv)
{
return pv_field(pv, ba_size);
}
uint64_t pv_pe_start(const struct physical_volume *pv)
{
return pv_field(pv, pe_start);
}
uint32_t pv_pe_count(const struct physical_volume *pv)
{
return pv_field(pv, pe_count);
}
uint32_t pv_pe_alloc_count(const struct physical_volume *pv)
{
return pv_field(pv, pe_alloc_count);
}
uint32_t pv_mda_count(const struct physical_volume *pv)
{
struct lvmcache_info *info;
info = lvmcache_info_from_pvid((const char *)&pv->id.uuid, 0);
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return info ? lvmcache_mda_count(info) : UINT64_C(0);
}
static int _count_unignored(struct metadata_area *mda, void *baton)
{
uint32_t *count = baton;
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if (!mda_is_ignored(mda))
(*count) ++;
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return 1;
}
uint32_t pv_mda_used_count(const struct physical_volume *pv)
{
struct lvmcache_info *info;
uint32_t used_count=0;
info = lvmcache_info_from_pvid((const char *)&pv->id.uuid, 0);
if (!info)
return 0;
lvmcache_foreach_mda(info, _count_unignored, &used_count);
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return used_count;
}
/**
* is_orphan - Determine whether a pv is an orphan based on its vg_name
* @pv: handle to the physical volume
*/
int is_orphan(const struct physical_volume *pv)
{
return is_orphan_vg(pv_field(pv, vg_name));
}
/**
* is_pv - Determine whether a pv is a real pv or dummy one
* @pv: handle to device
*/
int is_pv(const struct physical_volume *pv)
{
return (pv_field(pv, vg_name) ? 1 : 0);
}
int is_missing_pv(const struct physical_volume *pv)
{
return pv_field(pv, status) & MISSING_PV ? 1 : 0;
}
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int is_used_pv(const struct physical_volume *pv)
{
struct lvmcache_info *info;
uint32_t ext_flags;
if (!pv->fmt)
return 0;
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if (!is_orphan(pv))
return 1;
if (!(pv->fmt->features & FMT_PV_FLAGS))
return 0;
if (!(info = lvmcache_info_from_pvid((const char *)&pv->id, 0))) {
log_error("Failed to find cached info for PV %s.", pv_dev_name(pv));
return -1;
}
ext_flags = lvmcache_ext_flags(info);
return ext_flags & PV_EXT_USED ? 1 : 0;
}
char *pv_attr_dup(struct dm_pool *mem, const struct physical_volume *pv)
{
char *repstr;
int used = is_used_pv(pv);
if (!(repstr = dm_pool_zalloc(mem, 4))) {
log_error("dm_pool_alloc failed");
return NULL;
}
/*
* An allocatable PV is always used, so we don't need to show 'u'.
*/
repstr[0] = (pv->status & ALLOCATABLE_PV) ? 'a' : (used > 0) ? 'u' : '-';
repstr[1] = (pv->status & EXPORTED_VG) ? 'x' : '-';
repstr[2] = (pv->status & MISSING_PV) ? 'm' : '-';
return repstr;
}
uint64_t pv_mda_size(const struct physical_volume *pv)
{
struct lvmcache_info *info;
uint64_t min_mda_size = 0;
const char *pvid = (const char *)(&pv->id.uuid);
/* PVs could have 2 mdas of different sizes (rounding effect) */
if ((info = lvmcache_info_from_pvid(pvid, 0)))
min_mda_size = lvmcache_smallest_mda_size(info);
return min_mda_size;
}
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static int _pv_mda_free(struct metadata_area *mda, void *baton)
{
uint64_t mda_free;
uint64_t *freespace = baton;
if (!mda->ops->mda_free_sectors)
return 1;
mda_free = mda->ops->mda_free_sectors(mda);
if (mda_free < *freespace)
*freespace = mda_free;
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return 1;
}
uint64_t lvmcache_info_mda_free(struct lvmcache_info *info)
{
uint64_t freespace = UINT64_MAX;
if (info)
lvmcache_foreach_mda(info, _pv_mda_free, &freespace);
if (freespace == UINT64_MAX)
freespace = UINT64_C(0);
return freespace;
}
uint64_t pv_mda_free(const struct physical_volume *pv)
{
const char *pvid = (const char *)&pv->id.uuid;
struct lvmcache_info *info;
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if ((info = lvmcache_info_from_pvid(pvid, 0)))
return lvmcache_info_mda_free(info);
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return 0;
}
uint64_t pv_used(const struct physical_volume *pv)
{
uint64_t used;
if (!pv->pe_count)
used = 0LL;
else
used = (uint64_t) pv->pe_alloc_count * pv->pe_size;
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return used;
}
struct _pv_mda_set_ignored_baton {
unsigned mda_ignored;
struct dm_list *mdas_in_use, *mdas_ignored, *mdas_to_change;
};
static int _pv_mda_set_ignored_one(struct metadata_area *mda, void *baton)
{
struct _pv_mda_set_ignored_baton *b = baton;
struct metadata_area *vg_mda, *tmda;
if (mda_is_ignored(mda) && !b->mda_ignored) {
/* Changing an ignored mda to one in_use requires moving it */
dm_list_iterate_items_safe(vg_mda, tmda, b->mdas_ignored)
if (mda_locns_match(mda, vg_mda)) {
mda_set_ignored(vg_mda, b->mda_ignored);
dm_list_move(b->mdas_in_use, &vg_mda->list);
}
}
dm_list_iterate_items_safe(vg_mda, tmda, b->mdas_in_use)
if (mda_locns_match(mda, vg_mda))
/* Don't move mda: needs writing to disk. */
mda_set_ignored(vg_mda, b->mda_ignored);
mda_set_ignored(mda, b->mda_ignored);
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return 1;
}
unsigned pv_mda_set_ignored(const struct physical_volume *pv, unsigned mda_ignored)
{
struct lvmcache_info *info;
struct _pv_mda_set_ignored_baton baton;
struct metadata_area *mda;
if (!(info = lvmcache_info_from_pvid((const char *)&pv->id.uuid, 0)))
return_0;
baton.mda_ignored = mda_ignored;
baton.mdas_in_use = &pv->fid->metadata_areas_in_use;
baton.mdas_ignored = &pv->fid->metadata_areas_ignored;
baton.mdas_to_change = baton.mda_ignored ? baton.mdas_in_use : baton.mdas_ignored;
if (is_orphan(pv)) {
dm_list_iterate_items(mda, baton.mdas_to_change)
mda_set_ignored(mda, baton.mda_ignored);
return 1;
}
/*
* Do not allow disabling of the the last PV in a VG.
*/
if (pv_mda_used_count(pv) == vg_mda_used_count(pv->vg)) {
log_error("Cannot disable all metadata areas in volume group %s.",
pv->vg->name);
return 0;
}
/*
* Non-orphan case is more complex.
* If the PV's mdas are ignored, and we wish to un-ignore,
* we clear the bit and move them from the ignored mda list to the
* in_use list, ensuring the new state will get written to disk
* in the vg_write() path.
* If the PV's mdas are not ignored, and we are setting
* them to ignored, we set the bit but leave them on the in_use
* list, ensuring the new state will get written to disk in the
* vg_write() path.
*/
/* FIXME: Try not to update the cache here! Also, try to iterate over
* PV mdas only using the format instance's index somehow
* (i.e. try to avoid using mda_locn_match call). */
lvmcache_foreach_mda(info, _pv_mda_set_ignored_one, &baton);
return 1;
}
struct label *pv_label(const struct physical_volume *pv)
{
struct lvmcache_info *info =
lvmcache_info_from_pvid((const char *)&pv->id.uuid, 0);
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if (info)
return lvmcache_get_label(info);
/* process_each_pv() may create dummy PVs that have no label */
if (pv->vg && pv->dev)
log_error(INTERNAL_ERROR "PV %s unexpectedly not in cache.",
dev_name(pv->dev));
return NULL;
}