提交 3492ee72 编写于 作者: L Linus Torvalds

Merge tag 'dm-3.5-fixes' of git://git.kernel.org/pub/scm/linux/kernel/git/agk/linux-dm

Pull device-mapper fixes from Alasdair G Kergon:
 "Four minor thin provisioning fixes and correct and update dm-verity
  documentation."

* tag 'dm-3.5-fixes' of git://git.kernel.org/pub/scm/linux/kernel/git/agk/linux-dm:
  dm: verity fix documentation
  dm persistent data: fix allocation failure in space map checker init
  dm persistent data: handle space map checker creation failure
  dm persistent data: fix shadow_info_leak on dm_tm_destroy
  dm thin: commit metadata before creating metadata snapshot
...@@ -7,39 +7,39 @@ This target is read-only. ...@@ -7,39 +7,39 @@ This target is read-only.
Construction Parameters Construction Parameters
======================= =======================
<version> <dev> <hash_dev> <hash_start> <version> <dev> <hash_dev>
<data_block_size> <hash_block_size> <data_block_size> <hash_block_size>
<num_data_blocks> <hash_start_block> <num_data_blocks> <hash_start_block>
<algorithm> <digest> <salt> <algorithm> <digest> <salt>
<version> <version>
This is the version number of the on-disk format. This is the type of the on-disk hash format.
0 is the original format used in the Chromium OS. 0 is the original format used in the Chromium OS.
The salt is appended when hashing, digests are stored continuously and The salt is appended when hashing, digests are stored continuously and
the rest of the block is padded with zeros. the rest of the block is padded with zeros.
1 is the current format that should be used for new devices. 1 is the current format that should be used for new devices.
The salt is prepended when hashing and each digest is The salt is prepended when hashing and each digest is
padded with zeros to the power of two. padded with zeros to the power of two.
<dev> <dev>
This is the device containing the data the integrity of which needs to be This is the device containing data, the integrity of which needs to be
checked. It may be specified as a path, like /dev/sdaX, or a device number, checked. It may be specified as a path, like /dev/sdaX, or a device number,
<major>:<minor>. <major>:<minor>.
<hash_dev> <hash_dev>
This is the device that that supplies the hash tree data. It may be This is the device that supplies the hash tree data. It may be
specified similarly to the device path and may be the same device. If the specified similarly to the device path and may be the same device. If the
same device is used, the hash_start should be outside of the dm-verity same device is used, the hash_start should be outside the configured
configured device size. dm-verity device.
<data_block_size> <data_block_size>
The block size on a data device. Each block corresponds to one digest on The block size on a data device in bytes.
the hash device. Each block corresponds to one digest on the hash device.
<hash_block_size> <hash_block_size>
The size of a hash block. The size of a hash block in bytes.
<num_data_blocks> <num_data_blocks>
The number of data blocks on the data device. Additional blocks are The number of data blocks on the data device. Additional blocks are
...@@ -65,7 +65,7 @@ Construction Parameters ...@@ -65,7 +65,7 @@ Construction Parameters
Theory of operation Theory of operation
=================== ===================
dm-verity is meant to be setup as part of a verified boot path. This dm-verity is meant to be set up as part of a verified boot path. This
may be anything ranging from a boot using tboot or trustedgrub to just may be anything ranging from a boot using tboot or trustedgrub to just
booting from a known-good device (like a USB drive or CD). booting from a known-good device (like a USB drive or CD).
...@@ -73,20 +73,20 @@ When a dm-verity device is configured, it is expected that the caller ...@@ -73,20 +73,20 @@ When a dm-verity device is configured, it is expected that the caller
has been authenticated in some way (cryptographic signatures, etc). has been authenticated in some way (cryptographic signatures, etc).
After instantiation, all hashes will be verified on-demand during After instantiation, all hashes will be verified on-demand during
disk access. If they cannot be verified up to the root node of the disk access. If they cannot be verified up to the root node of the
tree, the root hash, then the I/O will fail. This should identify tree, the root hash, then the I/O will fail. This should detect
tampering with any data on the device and the hash data. tampering with any data on the device and the hash data.
Cryptographic hashes are used to assert the integrity of the device on a Cryptographic hashes are used to assert the integrity of the device on a
per-block basis. This allows for a lightweight hash computation on first read per-block basis. This allows for a lightweight hash computation on first read
into the page cache. Block hashes are stored linearly-aligned to the nearest into the page cache. Block hashes are stored linearly, aligned to the nearest
block the size of a page. block size.
Hash Tree Hash Tree
--------- ---------
Each node in the tree is a cryptographic hash. If it is a leaf node, the hash Each node in the tree is a cryptographic hash. If it is a leaf node, the hash
is of some block data on disk. If it is an intermediary node, then the hash is of some data block on disk is calculated. If it is an intermediary node,
of a number of child nodes. the hash of a number of child nodes is calculated.
Each entry in the tree is a collection of neighboring nodes that fit in one Each entry in the tree is a collection of neighboring nodes that fit in one
block. The number is determined based on block_size and the size of the block. The number is determined based on block_size and the size of the
...@@ -110,63 +110,23 @@ alg = sha256, num_blocks = 32768, block_size = 4096 ...@@ -110,63 +110,23 @@ alg = sha256, num_blocks = 32768, block_size = 4096
On-disk format On-disk format
============== ==============
Below is the recommended on-disk format. The verity kernel code does not The verity kernel code does not read the verity metadata on-disk header.
read the on-disk header. It only reads the hash blocks which directly It only reads the hash blocks which directly follow the header.
follow the header. It is expected that a user-space tool will verify the It is expected that a user-space tool will verify the integrity of the
integrity of the verity_header and then call dmsetup with the correct verity header.
parameters. Alternatively, the header can be omitted and the dmsetup
parameters can be passed via the kernel command-line in a rooted chain
of trust where the command-line is verified.
The on-disk format is especially useful in cases where the hash blocks Alternatively, the header can be omitted and the dmsetup parameters can
are on a separate partition. The magic number allows easy identification be passed via the kernel command-line in a rooted chain of trust where
of the partition contents. Alternatively, the hash blocks can be stored the command-line is verified.
in the same partition as the data to be verified. In such a configuration
the filesystem on the partition would be sized a little smaller than
the full-partition, leaving room for the hash blocks.
struct superblock {
uint8_t signature[8]
"verity\0\0";
uint8_t version;
1 - current format
uint8_t data_block_bits;
log2(data block size)
uint8_t hash_block_bits;
log2(hash block size)
uint8_t pad1[1];
zero padding
uint16_t salt_size;
big-endian salt size
uint8_t pad2[2];
zero padding
uint32_t data_blocks_hi;
big-endian high 32 bits of the 64-bit number of data blocks
uint32_t data_blocks_lo;
big-endian low 32 bits of the 64-bit number of data blocks
uint8_t algorithm[16];
cryptographic algorithm
uint8_t salt[384];
salt (the salt size is specified above)
uint8_t pad3[88];
zero padding to 512-byte boundary
}
Directly following the header (and with sector number padded to the next hash Directly following the header (and with sector number padded to the next hash
block boundary) are the hash blocks which are stored a depth at a time block boundary) are the hash blocks which are stored a depth at a time
(starting from the root), sorted in order of increasing index. (starting from the root), sorted in order of increasing index.
The full specification of kernel parameters and on-disk metadata format
is available at the cryptsetup project's wiki page
http://code.google.com/p/cryptsetup/wiki/DMVerity
Status Status
====== ======
V (for Valid) is returned if every check performed so far was valid. V (for Valid) is returned if every check performed so far was valid.
...@@ -174,21 +134,22 @@ If any check failed, C (for Corruption) is returned. ...@@ -174,21 +134,22 @@ If any check failed, C (for Corruption) is returned.
Example Example
======= =======
Set up a device:
Setup a device: # dmsetup create vroot --readonly --table \
dmsetup create vroot --table \ "0 2097152 verity 1 /dev/sda1 /dev/sda2 4096 4096 262144 1 sha256 "\
"0 2097152 "\
"verity 1 /dev/sda1 /dev/sda2 4096 4096 2097152 1 "\
"4392712ba01368efdf14b05c76f9e4df0d53664630b5d48632ed17a137f39076 "\ "4392712ba01368efdf14b05c76f9e4df0d53664630b5d48632ed17a137f39076 "\
"1234000000000000000000000000000000000000000000000000000000000000" "1234000000000000000000000000000000000000000000000000000000000000"
A command line tool veritysetup is available to compute or verify A command line tool veritysetup is available to compute or verify
the hash tree or activate the kernel driver. This is available from the hash tree or activate the kernel device. This is available from
the LVM2 upstream repository and may be supplied as a package called the cryptsetup upstream repository http://code.google.com/p/cryptsetup/
device-mapper-verity-tools: (as a libcryptsetup extension).
git://sources.redhat.com/git/lvm2
http://sourceware.org/git/?p=lvm2.git Create hash on the device:
http://sourceware.org/cgi-bin/cvsweb.cgi/LVM2/verity?cvsroot=lvm2 # veritysetup format /dev/sda1 /dev/sda2
...
veritysetup -a vroot /dev/sda1 /dev/sda2 \ Root hash: 4392712ba01368efdf14b05c76f9e4df0d53664630b5d48632ed17a137f39076
4392712ba01368efdf14b05c76f9e4df0d53664630b5d48632ed17a137f39076
Activate the device:
# veritysetup create vroot /dev/sda1 /dev/sda2 \
4392712ba01368efdf14b05c76f9e4df0d53664630b5d48632ed17a137f39076
...@@ -2292,6 +2292,13 @@ static int process_reserve_metadata_snap_mesg(unsigned argc, char **argv, struct ...@@ -2292,6 +2292,13 @@ static int process_reserve_metadata_snap_mesg(unsigned argc, char **argv, struct
if (r) if (r)
return r; return r;
r = dm_pool_commit_metadata(pool->pmd);
if (r) {
DMERR("%s: dm_pool_commit_metadata() failed, error = %d",
__func__, r);
return r;
}
r = dm_pool_reserve_metadata_snap(pool->pmd); r = dm_pool_reserve_metadata_snap(pool->pmd);
if (r) if (r)
DMWARN("reserve_metadata_snap message failed."); DMWARN("reserve_metadata_snap message failed.");
......
...@@ -8,6 +8,7 @@ ...@@ -8,6 +8,7 @@
#include <linux/device-mapper.h> #include <linux/device-mapper.h>
#include <linux/export.h> #include <linux/export.h>
#include <linux/vmalloc.h>
#ifdef CONFIG_DM_DEBUG_SPACE_MAPS #ifdef CONFIG_DM_DEBUG_SPACE_MAPS
...@@ -89,13 +90,23 @@ static int ca_create(struct count_array *ca, struct dm_space_map *sm) ...@@ -89,13 +90,23 @@ static int ca_create(struct count_array *ca, struct dm_space_map *sm)
ca->nr = nr_blocks; ca->nr = nr_blocks;
ca->nr_free = nr_blocks; ca->nr_free = nr_blocks;
ca->counts = kzalloc(sizeof(*ca->counts) * nr_blocks, GFP_KERNEL);
if (!ca->counts) if (!nr_blocks)
return -ENOMEM; ca->counts = NULL;
else {
ca->counts = vzalloc(sizeof(*ca->counts) * nr_blocks);
if (!ca->counts)
return -ENOMEM;
}
return 0; return 0;
} }
static void ca_destroy(struct count_array *ca)
{
vfree(ca->counts);
}
static int ca_load(struct count_array *ca, struct dm_space_map *sm) static int ca_load(struct count_array *ca, struct dm_space_map *sm)
{ {
int r; int r;
...@@ -126,12 +137,14 @@ static int ca_load(struct count_array *ca, struct dm_space_map *sm) ...@@ -126,12 +137,14 @@ static int ca_load(struct count_array *ca, struct dm_space_map *sm)
static int ca_extend(struct count_array *ca, dm_block_t extra_blocks) static int ca_extend(struct count_array *ca, dm_block_t extra_blocks)
{ {
dm_block_t nr_blocks = ca->nr + extra_blocks; dm_block_t nr_blocks = ca->nr + extra_blocks;
uint32_t *counts = kzalloc(sizeof(*counts) * nr_blocks, GFP_KERNEL); uint32_t *counts = vzalloc(sizeof(*counts) * nr_blocks);
if (!counts) if (!counts)
return -ENOMEM; return -ENOMEM;
memcpy(counts, ca->counts, sizeof(*counts) * ca->nr); if (ca->counts) {
kfree(ca->counts); memcpy(counts, ca->counts, sizeof(*counts) * ca->nr);
ca_destroy(ca);
}
ca->nr = nr_blocks; ca->nr = nr_blocks;
ca->nr_free += extra_blocks; ca->nr_free += extra_blocks;
ca->counts = counts; ca->counts = counts;
...@@ -151,11 +164,6 @@ static int ca_commit(struct count_array *old, struct count_array *new) ...@@ -151,11 +164,6 @@ static int ca_commit(struct count_array *old, struct count_array *new)
return 0; return 0;
} }
static void ca_destroy(struct count_array *ca)
{
kfree(ca->counts);
}
/*----------------------------------------------------------------*/ /*----------------------------------------------------------------*/
struct sm_checker { struct sm_checker {
...@@ -343,25 +351,25 @@ struct dm_space_map *dm_sm_checker_create(struct dm_space_map *sm) ...@@ -343,25 +351,25 @@ struct dm_space_map *dm_sm_checker_create(struct dm_space_map *sm)
int r; int r;
struct sm_checker *smc; struct sm_checker *smc;
if (!sm) if (IS_ERR_OR_NULL(sm))
return NULL; return ERR_PTR(-EINVAL);
smc = kmalloc(sizeof(*smc), GFP_KERNEL); smc = kmalloc(sizeof(*smc), GFP_KERNEL);
if (!smc) if (!smc)
return NULL; return ERR_PTR(-ENOMEM);
memcpy(&smc->sm, &ops_, sizeof(smc->sm)); memcpy(&smc->sm, &ops_, sizeof(smc->sm));
r = ca_create(&smc->old_counts, sm); r = ca_create(&smc->old_counts, sm);
if (r) { if (r) {
kfree(smc); kfree(smc);
return NULL; return ERR_PTR(r);
} }
r = ca_create(&smc->counts, sm); r = ca_create(&smc->counts, sm);
if (r) { if (r) {
ca_destroy(&smc->old_counts); ca_destroy(&smc->old_counts);
kfree(smc); kfree(smc);
return NULL; return ERR_PTR(r);
} }
smc->real_sm = sm; smc->real_sm = sm;
...@@ -371,7 +379,7 @@ struct dm_space_map *dm_sm_checker_create(struct dm_space_map *sm) ...@@ -371,7 +379,7 @@ struct dm_space_map *dm_sm_checker_create(struct dm_space_map *sm)
ca_destroy(&smc->counts); ca_destroy(&smc->counts);
ca_destroy(&smc->old_counts); ca_destroy(&smc->old_counts);
kfree(smc); kfree(smc);
return NULL; return ERR_PTR(r);
} }
r = ca_commit(&smc->old_counts, &smc->counts); r = ca_commit(&smc->old_counts, &smc->counts);
...@@ -379,7 +387,7 @@ struct dm_space_map *dm_sm_checker_create(struct dm_space_map *sm) ...@@ -379,7 +387,7 @@ struct dm_space_map *dm_sm_checker_create(struct dm_space_map *sm)
ca_destroy(&smc->counts); ca_destroy(&smc->counts);
ca_destroy(&smc->old_counts); ca_destroy(&smc->old_counts);
kfree(smc); kfree(smc);
return NULL; return ERR_PTR(r);
} }
return &smc->sm; return &smc->sm;
...@@ -391,25 +399,25 @@ struct dm_space_map *dm_sm_checker_create_fresh(struct dm_space_map *sm) ...@@ -391,25 +399,25 @@ struct dm_space_map *dm_sm_checker_create_fresh(struct dm_space_map *sm)
int r; int r;
struct sm_checker *smc; struct sm_checker *smc;
if (!sm) if (IS_ERR_OR_NULL(sm))
return NULL; return ERR_PTR(-EINVAL);
smc = kmalloc(sizeof(*smc), GFP_KERNEL); smc = kmalloc(sizeof(*smc), GFP_KERNEL);
if (!smc) if (!smc)
return NULL; return ERR_PTR(-ENOMEM);
memcpy(&smc->sm, &ops_, sizeof(smc->sm)); memcpy(&smc->sm, &ops_, sizeof(smc->sm));
r = ca_create(&smc->old_counts, sm); r = ca_create(&smc->old_counts, sm);
if (r) { if (r) {
kfree(smc); kfree(smc);
return NULL; return ERR_PTR(r);
} }
r = ca_create(&smc->counts, sm); r = ca_create(&smc->counts, sm);
if (r) { if (r) {
ca_destroy(&smc->old_counts); ca_destroy(&smc->old_counts);
kfree(smc); kfree(smc);
return NULL; return ERR_PTR(r);
} }
smc->real_sm = sm; smc->real_sm = sm;
......
...@@ -290,7 +290,16 @@ struct dm_space_map *dm_sm_disk_create(struct dm_transaction_manager *tm, ...@@ -290,7 +290,16 @@ struct dm_space_map *dm_sm_disk_create(struct dm_transaction_manager *tm,
dm_block_t nr_blocks) dm_block_t nr_blocks)
{ {
struct dm_space_map *sm = dm_sm_disk_create_real(tm, nr_blocks); struct dm_space_map *sm = dm_sm_disk_create_real(tm, nr_blocks);
return dm_sm_checker_create_fresh(sm); struct dm_space_map *smc;
if (IS_ERR_OR_NULL(sm))
return sm;
smc = dm_sm_checker_create_fresh(sm);
if (IS_ERR(smc))
dm_sm_destroy(sm);
return smc;
} }
EXPORT_SYMBOL_GPL(dm_sm_disk_create); EXPORT_SYMBOL_GPL(dm_sm_disk_create);
......
...@@ -138,6 +138,9 @@ EXPORT_SYMBOL_GPL(dm_tm_create_non_blocking_clone); ...@@ -138,6 +138,9 @@ EXPORT_SYMBOL_GPL(dm_tm_create_non_blocking_clone);
void dm_tm_destroy(struct dm_transaction_manager *tm) void dm_tm_destroy(struct dm_transaction_manager *tm)
{ {
if (!tm->is_clone)
wipe_shadow_table(tm);
kfree(tm); kfree(tm);
} }
EXPORT_SYMBOL_GPL(dm_tm_destroy); EXPORT_SYMBOL_GPL(dm_tm_destroy);
...@@ -344,8 +347,10 @@ static int dm_tm_create_internal(struct dm_block_manager *bm, ...@@ -344,8 +347,10 @@ static int dm_tm_create_internal(struct dm_block_manager *bm,
} }
*sm = dm_sm_checker_create(inner); *sm = dm_sm_checker_create(inner);
if (!*sm) if (IS_ERR(*sm)) {
r = PTR_ERR(*sm);
goto bad2; goto bad2;
}
} else { } else {
r = dm_bm_write_lock(dm_tm_get_bm(*tm), sb_location, r = dm_bm_write_lock(dm_tm_get_bm(*tm), sb_location,
...@@ -364,8 +369,10 @@ static int dm_tm_create_internal(struct dm_block_manager *bm, ...@@ -364,8 +369,10 @@ static int dm_tm_create_internal(struct dm_block_manager *bm,
} }
*sm = dm_sm_checker_create(inner); *sm = dm_sm_checker_create(inner);
if (!*sm) if (IS_ERR(*sm)) {
r = PTR_ERR(*sm);
goto bad2; goto bad2;
}
} }
return 0; return 0;
......
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