/*
* GRUB -- GRand Unified Bootloader
* Copyright (C) 2006,2007,2008,2009,2011 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
#include
#include
#ifdef GRUB_UTIL
#include
#include
#endif
GRUB_MOD_LICENSE ("GPLv3+");
#define LDM_GUID_STRLEN 64
#define LDM_NAME_STRLEN 32
typedef grub_uint8_t *grub_ldm_id_t;
enum { STRIPE = 1, SPANNED = 2, RAID5 = 3 };
#define LDM_LABEL_SECTOR 6
struct grub_ldm_vblk {
char magic[4];
grub_uint8_t unused1[12];
grub_uint16_t update_status;
grub_uint8_t flags;
grub_uint8_t type;
grub_uint32_t unused2;
grub_uint8_t dynamic[104];
} __attribute__ ((packed));
#define LDM_VBLK_MAGIC "VBLK"
enum
{
STATUS_CONSISTENT = 0,
STATUS_STILL_ACTIVE = 1,
STATUS_NOT_ACTIVE_YET = 2
};
enum
{
ENTRY_COMPONENT = 0x32,
ENTRY_PARTITION = 0x33,
ENTRY_DISK = 0x34,
ENTRY_VOLUME = 0x51,
};
struct grub_ldm_label
{
char magic[8];
grub_uint32_t unused1;
grub_uint16_t ver_major;
grub_uint16_t ver_minor;
grub_uint8_t unused2[32];
char disk_guid[LDM_GUID_STRLEN];
char host_guid[LDM_GUID_STRLEN];
char group_guid[LDM_GUID_STRLEN];
char group_name[LDM_NAME_STRLEN];
grub_uint8_t unused3[11];
grub_uint64_t pv_start;
grub_uint64_t pv_size;
grub_uint64_t config_start;
grub_uint64_t config_size;
} __attribute__ ((packed));
#define LDM_MAGIC "PRIVHEAD"
static inline grub_uint64_t
read_int (grub_uint8_t *in, grub_size_t s)
{
grub_uint8_t *ptr2;
grub_uint64_t ret;
ret = 0;
for (ptr2 = in; ptr2 < in + s; ptr2++)
{
ret <<= 8;
ret |= *ptr2;
}
return ret;
}
static const grub_gpt_part_type_t ldm_type = GRUB_GPT_PARTITION_TYPE_LDM;
/* Helper for gpt_ldm_sector. */
static int
gpt_ldm_sector_iter (grub_disk_t disk, const grub_partition_t p, void *data)
{
grub_disk_addr_t *sector = data;
struct grub_gpt_partentry gptdata;
grub_partition_t p2;
p2 = disk->partition;
disk->partition = p->parent;
if (grub_disk_read (disk, p->offset, p->index,
sizeof (gptdata), &gptdata))
{
disk->partition = p2;
return 0;
}
disk->partition = p2;
if (! grub_memcmp (&gptdata.type, &ldm_type, 16))
{
*sector = p->start + p->len - 1;
return 1;
}
return 0;
}
static grub_disk_addr_t
gpt_ldm_sector (grub_disk_t dsk)
{
grub_disk_addr_t sector = 0;
grub_err_t err;
err = grub_gpt_partition_map_iterate (dsk, gpt_ldm_sector_iter, §or);
if (err)
{
grub_errno = GRUB_ERR_NONE;
return 0;
}
return sector;
}
static struct grub_diskfilter_vg *
make_vg (grub_disk_t disk,
const struct grub_ldm_label *label)
{
grub_disk_addr_t startsec, endsec, cursec;
struct grub_diskfilter_vg *vg;
grub_err_t err;
/* First time we see this volume group. We've to create the
whole volume group structure. */
vg = grub_malloc (sizeof (*vg));
if (! vg)
return NULL;
vg->extent_size = 1;
vg->name = grub_malloc (LDM_NAME_STRLEN + 1);
vg->uuid = grub_malloc (LDM_GUID_STRLEN + 1);
if (! vg->uuid || !vg->name)
{
grub_free (vg->uuid);
grub_free (vg->name);
return NULL;
}
grub_memcpy (vg->uuid, label->group_guid, LDM_GUID_STRLEN);
grub_memcpy (vg->name, label->group_name, LDM_NAME_STRLEN);
vg->name[LDM_NAME_STRLEN] = 0;
vg->uuid[LDM_GUID_STRLEN] = 0;
vg->uuid_len = grub_strlen (vg->uuid);
vg->lvs = NULL;
vg->pvs = NULL;
startsec = grub_be_to_cpu64 (label->config_start);
endsec = startsec + grub_be_to_cpu64 (label->config_size);
/* First find disks. */
for (cursec = startsec + 0x12; cursec < endsec; cursec++)
{
struct grub_ldm_vblk vblk[GRUB_DISK_SECTOR_SIZE
/ sizeof (struct grub_ldm_vblk)];
unsigned i;
err = grub_disk_read (disk, cursec, 0,
sizeof(vblk), &vblk);
if (err)
goto fail2;
for (i = 0; i < ARRAY_SIZE (vblk); i++)
{
struct grub_diskfilter_pv *pv;
grub_uint8_t *ptr;
if (grub_memcmp (vblk[i].magic, LDM_VBLK_MAGIC,
sizeof (vblk[i].magic)) != 0)
continue;
if (grub_be_to_cpu16 (vblk[i].update_status)
!= STATUS_CONSISTENT
&& grub_be_to_cpu16 (vblk[i].update_status)
!= STATUS_STILL_ACTIVE)
continue;
if (vblk[i].type != ENTRY_DISK)
continue;
pv = grub_zalloc (sizeof (*pv));
if (!pv)
goto fail2;
pv->disk = 0;
ptr = vblk[i].dynamic;
if (ptr + *ptr + 1 >= vblk[i].dynamic
+ sizeof (vblk[i].dynamic))
{
grub_free (pv);
goto fail2;
}
pv->internal_id = grub_malloc (ptr[0] + 2);
if (!pv->internal_id)
{
grub_free (pv);
goto fail2;
}
grub_memcpy (pv->internal_id, ptr, (grub_size_t) ptr[0] + 1);
pv->internal_id[(grub_size_t) ptr[0] + 1] = 0;
ptr += *ptr + 1;
if (ptr + *ptr + 1 >= vblk[i].dynamic
+ sizeof (vblk[i].dynamic))
{
grub_free (pv);
goto fail2;
}
/* ptr = name. */
ptr += *ptr + 1;
if (ptr + *ptr + 1
>= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
grub_free (pv);
goto fail2;
}
pv->id.uuidlen = *ptr;
pv->id.uuid = grub_malloc (pv->id.uuidlen + 1);
grub_memcpy (pv->id.uuid, ptr + 1, pv->id.uuidlen);
pv->id.uuid[pv->id.uuidlen] = 0;
pv->next = vg->pvs;
vg->pvs = pv;
}
}
/* Then find LVs. */
for (cursec = startsec + 0x12; cursec < endsec; cursec++)
{
struct grub_ldm_vblk vblk[GRUB_DISK_SECTOR_SIZE
/ sizeof (struct grub_ldm_vblk)];
unsigned i;
err = grub_disk_read (disk, cursec, 0,
sizeof(vblk), &vblk);
if (err)
goto fail2;
for (i = 0; i < ARRAY_SIZE (vblk); i++)
{
struct grub_diskfilter_lv *lv;
grub_uint8_t *ptr;
if (grub_memcmp (vblk[i].magic, LDM_VBLK_MAGIC,
sizeof (vblk[i].magic)) != 0)
continue;
if (grub_be_to_cpu16 (vblk[i].update_status)
!= STATUS_CONSISTENT
&& grub_be_to_cpu16 (vblk[i].update_status)
!= STATUS_STILL_ACTIVE)
continue;
if (vblk[i].type != ENTRY_VOLUME)
continue;
lv = grub_zalloc (sizeof (*lv));
if (!lv)
goto fail2;
lv->vg = vg;
lv->segment_count = 1;
lv->segment_alloc = 1;
lv->visible = 1;
lv->segments = grub_zalloc (sizeof (*lv->segments));
if (!lv->segments)
goto fail2;
lv->segments->start_extent = 0;
lv->segments->type = GRUB_DISKFILTER_MIRROR;
lv->segments->node_count = 0;
lv->segments->node_alloc = 8;
lv->segments->nodes = grub_zalloc (sizeof (*lv->segments->nodes)
* lv->segments->node_alloc);
if (!lv->segments->nodes)
goto fail2;
ptr = vblk[i].dynamic;
if (ptr + *ptr + 1 >= vblk[i].dynamic
+ sizeof (vblk[i].dynamic))
{
grub_free (lv);
goto fail2;
}
lv->internal_id = grub_malloc ((grub_size_t) ptr[0] + 2);
if (!lv->internal_id)
{
grub_free (lv);
goto fail2;
}
grub_memcpy (lv->internal_id, ptr, ptr[0] + 1);
lv->internal_id[ptr[0] + 1] = 0;
ptr += *ptr + 1;
if (ptr + *ptr + 1 >= vblk[i].dynamic
+ sizeof (vblk[i].dynamic))
{
grub_free (lv);
goto fail2;
}
lv->name = grub_malloc (*ptr + 1);
if (!lv->name)
{
grub_free (lv->internal_id);
grub_free (lv);
goto fail2;
}
grub_memcpy (lv->name, ptr + 1, *ptr);
lv->name[*ptr] = 0;
lv->fullname = grub_xasprintf ("ldm/%s/%s",
vg->uuid, lv->name);
if (!lv->fullname)
{
grub_free (lv->internal_id);
grub_free (lv->name);
grub_free (lv);
goto fail2;
}
ptr += *ptr + 1;
if (ptr + *ptr + 1
>= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
grub_free (lv->internal_id);
grub_free (lv->name);
grub_free (lv);
goto fail2;
}
/* ptr = volume type. */
ptr += *ptr + 1;
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
grub_free (lv->internal_id);
grub_free (lv->name);
grub_free (lv);
goto fail2;
}
/* ptr = flags. */
ptr += *ptr + 1;
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
grub_free (lv->internal_id);
grub_free (lv->name);
grub_free (lv);
goto fail2;
}
/* Skip state, type, unknown, volume number, zeros, flags. */
ptr += 14 + 1 + 1 + 1 + 3 + 1;
/* ptr = number of children. */
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
grub_free (lv->internal_id);
grub_free (lv->name);
grub_free (lv);
goto fail2;
}
ptr += *ptr + 1;
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
grub_free (lv->internal_id);
grub_free (lv->name);
grub_free (lv);
goto fail2;
}
/* Skip 2 more fields. */
ptr += 8 + 8;
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic)
|| ptr + *ptr + 1>= vblk[i].dynamic
+ sizeof (vblk[i].dynamic))
{
grub_free (lv->internal_id);
grub_free (lv->name);
grub_free (lv);
goto fail2;
}
lv->size = read_int (ptr + 1, *ptr);
lv->segments->extent_count = lv->size;
lv->next = vg->lvs;
vg->lvs = lv;
}
}
/* Now the components. */
for (cursec = startsec + 0x12; cursec < endsec; cursec++)
{
struct grub_ldm_vblk vblk[GRUB_DISK_SECTOR_SIZE
/ sizeof (struct grub_ldm_vblk)];
unsigned i;
err = grub_disk_read (disk, cursec, 0,
sizeof(vblk), &vblk);
if (err)
goto fail2;
for (i = 0; i < ARRAY_SIZE (vblk); i++)
{
struct grub_diskfilter_lv *comp;
struct grub_diskfilter_lv *lv;
grub_uint8_t type;
grub_uint8_t *ptr;
if (grub_memcmp (vblk[i].magic, LDM_VBLK_MAGIC,
sizeof (vblk[i].magic)) != 0)
continue;
if (grub_be_to_cpu16 (vblk[i].update_status)
!= STATUS_CONSISTENT
&& grub_be_to_cpu16 (vblk[i].update_status)
!= STATUS_STILL_ACTIVE)
continue;
if (vblk[i].type != ENTRY_COMPONENT)
continue;
comp = grub_zalloc (sizeof (*comp));
if (!comp)
goto fail2;
comp->visible = 0;
comp->name = 0;
comp->fullname = 0;
ptr = vblk[i].dynamic;
if (ptr + *ptr + 1 >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
goto fail2;
}
comp->internal_id = grub_malloc ((grub_size_t) ptr[0] + 2);
if (!comp->internal_id)
{
grub_free (comp);
goto fail2;
}
grub_memcpy (comp->internal_id, ptr, ptr[0] + 1);
comp->internal_id[ptr[0] + 1] = 0;
ptr += *ptr + 1;
if (ptr + *ptr + 1 >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
grub_free (comp->internal_id);
grub_free (comp);
goto fail2;
}
/* ptr = name. */
ptr += *ptr + 1;
if (ptr + *ptr + 1 >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
grub_free (comp->internal_id);
grub_free (comp);
goto fail2;
}
/* ptr = state. */
ptr += *ptr + 1;
type = *ptr++;
/* skip zeros. */
ptr += 4;
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
grub_free (comp->internal_id);
grub_free (comp);
goto fail2;
}
/* ptr = number of children. */
ptr += *ptr + 1;
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
grub_free (comp->internal_id);
grub_free (comp);
goto fail2;
}
ptr += 8 + 8;
if (ptr + *ptr + 1 >= vblk[i].dynamic
+ sizeof (vblk[i].dynamic))
{
grub_free (comp->internal_id);
grub_free (comp);
goto fail2;
}
for (lv = vg->lvs; lv; lv = lv->next)
{
if (lv->internal_id[0] == ptr[0]
&& grub_memcmp (lv->internal_id + 1, ptr + 1, ptr[0]) == 0)
break;
}
if (!lv)
{
grub_free (comp->internal_id);
grub_free (comp);
continue;
}
comp->size = lv->size;
if (type == SPANNED)
{
comp->segment_alloc = 8;
comp->segment_count = 0;
comp->segments = grub_malloc (sizeof (*comp->segments)
* comp->segment_alloc);
if (!comp->segments)
goto fail2;
}
else
{
comp->segment_alloc = 1;
comp->segment_count = 1;
comp->segments = grub_malloc (sizeof (*comp->segments));
if (!comp->segments)
goto fail2;
comp->segments->start_extent = 0;
comp->segments->extent_count = lv->size;
comp->segments->layout = 0;
if (type == STRIPE)
comp->segments->type = GRUB_DISKFILTER_STRIPED;
else if (type == RAID5)
{
comp->segments->type = GRUB_DISKFILTER_RAID5;
comp->segments->layout = GRUB_RAID_LAYOUT_SYMMETRIC_MASK;
}
else
goto fail2;
ptr += *ptr + 1;
ptr++;
if (!(vblk[i].flags & 0x10))
goto fail2;
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic)
|| ptr + *ptr + 1 >= vblk[i].dynamic
+ sizeof (vblk[i].dynamic))
{
grub_free (comp->internal_id);
grub_free (comp);
goto fail2;
}
comp->segments->stripe_size = read_int (ptr + 1, *ptr);
ptr += *ptr + 1;
if (ptr + *ptr + 1 >= vblk[i].dynamic
+ sizeof (vblk[i].dynamic))
{
grub_free (comp->internal_id);
grub_free (comp);
goto fail2;
}
comp->segments->node_count = read_int (ptr + 1, *ptr);
comp->segments->node_alloc = comp->segments->node_count;
comp->segments->nodes = grub_zalloc (sizeof (*comp->segments->nodes)
* comp->segments->node_alloc);
if (!lv->segments->nodes)
goto fail2;
}
if (lv->segments->node_alloc == lv->segments->node_count)
{
void *t;
lv->segments->node_alloc *= 2;
t = grub_realloc (lv->segments->nodes,
sizeof (*lv->segments->nodes)
* lv->segments->node_alloc);
if (!t)
goto fail2;
lv->segments->nodes = t;
}
lv->segments->nodes[lv->segments->node_count].pv = 0;
lv->segments->nodes[lv->segments->node_count].start = 0;
lv->segments->nodes[lv->segments->node_count++].lv = comp;
comp->next = vg->lvs;
vg->lvs = comp;
}
}
/* Partitions. */
for (cursec = startsec + 0x12; cursec < endsec; cursec++)
{
struct grub_ldm_vblk vblk[GRUB_DISK_SECTOR_SIZE
/ sizeof (struct grub_ldm_vblk)];
unsigned i;
err = grub_disk_read (disk, cursec, 0,
sizeof(vblk), &vblk);
if (err)
goto fail2;
for (i = 0; i < ARRAY_SIZE (vblk); i++)
{
struct grub_diskfilter_lv *comp;
struct grub_diskfilter_node part;
grub_disk_addr_t start, size;
grub_uint8_t *ptr;
part.name = 0;
if (grub_memcmp (vblk[i].magic, LDM_VBLK_MAGIC,
sizeof (vblk[i].magic)) != 0)
continue;
if (grub_be_to_cpu16 (vblk[i].update_status)
!= STATUS_CONSISTENT
&& grub_be_to_cpu16 (vblk[i].update_status)
!= STATUS_STILL_ACTIVE)
continue;
if (vblk[i].type != ENTRY_PARTITION)
continue;
part.lv = 0;
part.pv = 0;
ptr = vblk[i].dynamic;
if (ptr + *ptr + 1 >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
goto fail2;
}
/* ID */
ptr += *ptr + 1;
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
goto fail2;
}
/* ptr = name. */
ptr += *ptr + 1;
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
goto fail2;
}
/* skip zeros and logcommit id. */
ptr += 4 + 8;
if (ptr + 16 >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
goto fail2;
}
part.start = read_int (ptr, 8);
start = read_int (ptr + 8, 8);
ptr += 16;
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic)
|| ptr + *ptr + 1 >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
goto fail2;
}
size = read_int (ptr + 1, *ptr);
ptr += *ptr + 1;
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic)
|| ptr + *ptr + 1 >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
goto fail2;
}
for (comp = vg->lvs; comp; comp = comp->next)
if (comp->internal_id[0] == ptr[0]
&& grub_memcmp (ptr + 1, comp->internal_id + 1,
comp->internal_id[0]) == 0)
goto out;
continue;
out:
if (ptr >= vblk[i].dynamic + sizeof (vblk[i].dynamic)
|| ptr + *ptr + 1 >= vblk[i].dynamic + sizeof (vblk[i].dynamic))
{
goto fail2;
}
ptr += *ptr + 1;
struct grub_diskfilter_pv *pv;
for (pv = vg->pvs; pv; pv = pv->next)
if (pv->internal_id[0] == ptr[0]
&& grub_memcmp (pv->internal_id + 1, ptr + 1, ptr[0]) == 0)
part.pv = pv;
if (comp->segment_alloc == 1)
{
unsigned index;
ptr += *ptr + 1;
if (ptr + *ptr + 1 >= vblk[i].dynamic
+ sizeof (vblk[i].dynamic))
{
goto fail2;
}
index = read_int (ptr + 1, *ptr);
if (index < comp->segments->node_count)
comp->segments->nodes[index] = part;
}
else
{
if (comp->segment_alloc == comp->segment_count)
{
void *t;
comp->segment_alloc *= 2;
t = grub_realloc (comp->segments,
comp->segment_alloc
* sizeof (*comp->segments));
if (!t)
goto fail2;
comp->segments = t;
}
comp->segments[comp->segment_count].start_extent = start;
comp->segments[comp->segment_count].extent_count = size;
comp->segments[comp->segment_count].type = GRUB_DISKFILTER_STRIPED;
comp->segments[comp->segment_count].node_count = 1;
comp->segments[comp->segment_count].node_alloc = 1;
comp->segments[comp->segment_count].nodes
= grub_malloc (sizeof (*comp->segments[comp->segment_count].nodes));
if (!comp->segments[comp->segment_count].nodes)
goto fail2;
comp->segments[comp->segment_count].nodes[0] = part;
comp->segment_count++;
}
}
}
if (grub_diskfilter_vg_register (vg))
goto fail2;
return vg;
fail2:
{
struct grub_diskfilter_lv *lv, *next_lv;
struct grub_diskfilter_pv *pv, *next_pv;
for (lv = vg->lvs; lv; lv = next_lv)
{
unsigned i;
for (i = 0; i < lv->segment_count; i++)
grub_free (lv->segments[i].nodes);
next_lv = lv->next;
grub_free (lv->segments);
grub_free (lv->internal_id);
grub_free (lv->name);
grub_free (lv->fullname);
grub_free (lv);
}
for (pv = vg->pvs; pv; pv = next_pv)
{
next_pv = pv->next;
grub_free (pv->id.uuid);
grub_free (pv);
}
}
grub_free (vg->uuid);
grub_free (vg);
return NULL;
}
static struct grub_diskfilter_vg *
grub_ldm_detect (grub_disk_t disk,
struct grub_diskfilter_pv_id *id,
grub_disk_addr_t *start_sector)
{
grub_err_t err;
struct grub_ldm_label label;
struct grub_diskfilter_vg *vg;
#ifdef GRUB_UTIL
grub_util_info ("scanning %s for LDM", disk->name);
#endif
{
int i;
for (i = 0; i < 3; i++)
{
grub_disk_addr_t sector = LDM_LABEL_SECTOR;
switch (i)
{
case 0:
sector = LDM_LABEL_SECTOR;
break;
case 1:
/* LDM is never inside a partition. */
if (disk->partition)
continue;
sector = grub_disk_get_size (disk);
if (sector == GRUB_DISK_SIZE_UNKNOWN)
continue;
sector--;
break;
/* FIXME: try the third copy. */
case 2:
sector = gpt_ldm_sector (disk);
if (!sector)
continue;
break;
}
err = grub_disk_read (disk, sector, 0,
sizeof(label), &label);
if (err)
return NULL;
if (grub_memcmp (label.magic, LDM_MAGIC, sizeof (label.magic)) == 0
&& grub_be_to_cpu16 (label.ver_major) == 0x02
&& grub_be_to_cpu16 (label.ver_minor) >= 0x0b
&& grub_be_to_cpu16 (label.ver_minor) <= 0x0c)
break;
}
/* Return if we didn't find a label. */
if (i == 3)
{
#ifdef GRUB_UTIL
grub_util_info ("no LDM signature found");
#endif
return NULL;
}
}
id->uuid = grub_malloc (LDM_GUID_STRLEN + 1);
if (!id->uuid)
return NULL;
grub_memcpy (id->uuid, label.disk_guid, LDM_GUID_STRLEN);
id->uuid[LDM_GUID_STRLEN] = 0;
id->uuidlen = grub_strlen ((char *) id->uuid);
*start_sector = grub_be_to_cpu64 (label.pv_start);
{
grub_size_t s;
for (s = 0; s < LDM_GUID_STRLEN && label.group_guid[s]; s++);
vg = grub_diskfilter_get_vg_by_uuid (s, label.group_guid);
if (! vg)
vg = make_vg (disk, &label);
}
if (!vg)
{
grub_free (id->uuid);
return NULL;
}
return vg;
}
#ifdef GRUB_UTIL
char *
grub_util_get_ldm (grub_disk_t disk, grub_disk_addr_t start)
{
struct grub_diskfilter_pv *pv = NULL;
struct grub_diskfilter_vg *vg = NULL;
struct grub_diskfilter_lv *res = 0, *lv, *res_lv = 0;
pv = grub_diskfilter_get_pv_from_disk (disk, &vg);
if (!pv)
return NULL;
for (lv = vg->lvs; lv; lv = lv->next)
if (lv->segment_count == 1 && lv->segments->node_count == 1
&& lv->segments->type == GRUB_DISKFILTER_STRIPED
&& lv->segments->nodes->pv == pv
&& lv->segments->nodes->start + pv->start_sector == start)
{
res_lv = lv;
break;
}
if (!res_lv)
return NULL;
for (lv = vg->lvs; lv; lv = lv->next)
if (lv->segment_count == 1 && lv->segments->node_count == 1
&& lv->segments->type == GRUB_DISKFILTER_MIRROR
&& lv->segments->nodes->lv == res_lv)
{
res = lv;
break;
}
if (res && res->fullname)
return grub_strdup (res->fullname);
return NULL;
}
int
grub_util_is_ldm (grub_disk_t disk)
{
int i;
for (i = 0; i < 3; i++)
{
grub_disk_addr_t sector = LDM_LABEL_SECTOR;
grub_err_t err;
struct grub_ldm_label label;
switch (i)
{
case 0:
sector = LDM_LABEL_SECTOR;
break;
case 1:
/* LDM is never inside a partition. */
if (disk->partition)
continue;
sector = grub_disk_get_size (disk);
if (sector == GRUB_DISK_SIZE_UNKNOWN)
continue;
sector--;
break;
/* FIXME: try the third copy. */
case 2:
sector = gpt_ldm_sector (disk);
if (!sector)
continue;
break;
}
err = grub_disk_read (disk, sector, 0, sizeof(label), &label);
if (err)
{
grub_errno = GRUB_ERR_NONE;
return 0;
}
/* This check is more relaxed on purpose. */
if (grub_memcmp (label.magic, LDM_MAGIC, sizeof (label.magic)) == 0)
return 1;
}
return 0;
}
grub_err_t
grub_util_ldm_embed (struct grub_disk *disk, unsigned int *nsectors,
unsigned int max_nsectors,
grub_embed_type_t embed_type,
grub_disk_addr_t **sectors)
{
struct grub_diskfilter_pv *pv = NULL;
struct grub_diskfilter_vg *vg;
struct grub_diskfilter_lv *lv;
unsigned i;
if (embed_type != GRUB_EMBED_PCBIOS)
return grub_error (GRUB_ERR_NOT_IMPLEMENTED_YET,
"LDM curently supports only PC-BIOS embedding");
if (disk->partition)
return grub_error (GRUB_ERR_BUG, "disk isn't LDM");
pv = grub_diskfilter_get_pv_from_disk (disk, &vg);
if (!pv)
return grub_error (GRUB_ERR_BUG, "disk isn't LDM");
for (lv = vg->lvs; lv; lv = lv->next)
{
struct grub_diskfilter_lv *comp;
if (!lv->visible || !lv->fullname)
continue;
if (lv->segment_count != 1)
continue;
if (lv->segments->type != GRUB_DISKFILTER_MIRROR
|| lv->segments->node_count != 1
|| lv->segments->start_extent != 0
|| lv->segments->extent_count != lv->size)
continue;
comp = lv->segments->nodes->lv;
if (!comp)
continue;
if (comp->segment_count != 1 || comp->size != lv->size)
continue;
if (comp->segments->type != GRUB_DISKFILTER_STRIPED
|| comp->segments->node_count != 1
|| comp->segments->start_extent != 0
|| comp->segments->extent_count != lv->size)
continue;
/* How to implement proper check is to be discussed. */
#if 1
if (1)
continue;
#else
if (grub_strcmp (lv->name, "Volume5") != 0)
continue;
#endif
if (lv->size < *nsectors)
return grub_error (GRUB_ERR_OUT_OF_RANGE,
/* TRANSLATORS: it's a partition for embedding,
not a partition embed into something. GRUB
install tools put core.img into a place
usable for bootloaders (called generically
"embedding zone") and this operation is
called "embedding". */
N_("your LDM embedding Partition is too small;"
" embedding won't be possible"));
*nsectors = lv->size;
if (*nsectors > max_nsectors)
*nsectors = max_nsectors;
*sectors = grub_malloc (*nsectors * sizeof (**sectors));
if (!*sectors)
return grub_errno;
for (i = 0; i < *nsectors; i++)
(*sectors)[i] = (lv->segments->nodes->start
+ comp->segments->nodes->start
+ comp->segments->nodes->pv->start_sector + i);
return GRUB_ERR_NONE;
}
return grub_error (GRUB_ERR_FILE_NOT_FOUND,
/* TRANSLATORS: it's a partition for embedding,
not a partition embed into something. */
N_("this LDM has no Embedding Partition;"
" embedding won't be possible"));
}
#endif
static struct grub_diskfilter grub_ldm_dev = {
.name = "ldm",
.detect = grub_ldm_detect,
.next = 0
};
GRUB_MOD_INIT (ldm)
{
grub_diskfilter_register_back (&grub_ldm_dev);
}
GRUB_MOD_FINI (ldm)
{
grub_diskfilter_unregister (&grub_ldm_dev);
}