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If the device size does not match the size requested
by --setphysicalvolumesize, then prompt the user.
Make the pvcreate checking/prompting code handle
multiple prompts for the same device, since the
new prompt can be in addition to the existing
prompt when the PV is in a VG.
As now we can properly recognize all paramerters for pool creation,
we may drop PASS_ARG_ defines and rely on '_UNSELECTED' or 0 entries
as being those without user given args.
When setting are not given on command line - 'update' function
fill them from profiles or configuration. For this 'profile' arg
was needed to be passed around and since 'VG' itself is not needed,
it's been all replaced with 'cmd, profile, extents_size' args.
Fix missing reset of '*settings' pointer when no args were given.
Handle cache_chunk settings like all other settings, so it is properly
updated only with non-zero settings and the existing cache-pool
chunk_size is not being reconfigured.
To more easily recognize unselected state from select '0' state
add new 'THIN_ZERO_UNSELECTED' enum.
Same applies to THIN_DISCARDS_UNSELECTED.
For those we no longer need to use PASS_ARG_ZERO or PASS_ARG_DISCARDS.
Like opt and val arrays in previous commit, combine duplicate
arrays for lv types and props in command.c and lvmcmdline.c.
Also move the command_names array to be defined in command.c
so it's consistent with the others.
Change run time access to the command_name struct
cmd->cname instead of indirectly through
cmd->command->cname. This removes the two run time
fields from struct command.
The new check_single_lv() function is called prior to the
existing process_single_lv(). If the check function returns 0,
the LV will not be processed.
The check_single_lv function is meant to be a standard method
to validate the combination of specific command + specific LV,
and decide if the combination is allowed. The check_single
function can be used by anything that calls process_each_lv.
As commands are migrated to take advantage of command
definitions, each command definition gets its own entry
point which calls process_each for itself, passing a
pair of check_single/process_single functions which can
be specific to the narrowly defined command def.
. Define a prototype for every lvm command.
. Match every user command with one definition.
. Generate help text and man pages from them.
The new file command-lines.in defines a prototype for every
unique lvm command. A unique lvm command is a unique
combination of: command name + required option args +
required positional args. Each of these prototypes also
includes the optional option args and optional positional
args that the command will accept, a description, and a
unique string ID for the definition. Any valid command
will match one of the prototypes.
Here's an example of the lvresize command definitions from
command-lines.in, there are three unique lvresize commands:
lvresize --size SizeMB LV
OO: --alloc Alloc, --autobackup Bool, --force,
--nofsck, --nosync, --noudevsync, --reportformat String, --resizefs,
--stripes Number, --stripesize SizeKB, --poolmetadatasize SizeMB
OP: PV ...
ID: lvresize_by_size
DESC: Resize an LV by a specified size.
lvresize LV PV ...
OO: --alloc Alloc, --autobackup Bool, --force,
--nofsck, --nosync, --noudevsync,
--reportformat String, --resizefs, --stripes Number, --stripesize SizeKB
ID: lvresize_by_pv
DESC: Resize an LV by specified PV extents.
FLAGS: SECONDARY_SYNTAX
lvresize --poolmetadatasize SizeMB LV_thinpool
OO: --alloc Alloc, --autobackup Bool, --force,
--nofsck, --nosync, --noudevsync,
--reportformat String, --stripes Number, --stripesize SizeKB
OP: PV ...
ID: lvresize_pool_metadata_by_size
DESC: Resize a pool metadata SubLV by a specified size.
The three commands have separate definitions because they have
different required parameters. Required parameters are specified
on the first line of the definition. Optional options are
listed after OO, and optional positional args are listed after OP.
This data is used to generate corresponding command definition
structures for lvm in command-lines.h. usage/help output is also
auto generated, so it is always in sync with the definitions.
Every user-entered command is compared against the set of
command structures, and matched with one. An error is
reported if an entered command does not have the required
parameters for any definition. The closest match is printed
as a suggestion, and running lvresize --help will display
the usage for each possible lvresize command.
The prototype syntax used for help/man output includes
required --option and positional args on the first line,
and optional --option and positional args enclosed in [ ]
on subsequent lines.
command_name <required_opt_args> <required_pos_args>
[ <optional_opt_args> ]
[ <optional_pos_args> ]
Command definitions that are not to be advertised/suggested
have the flag SECONDARY_SYNTAX. These commands will not be
printed in the normal help output.
Man page prototypes are also generated from the same original
command definitions, and are always in sync with the code
and help text.
Very early in command execution, a matching command definition
is found. lvm then knows the operation being done, and that
the provided args conform to the definition. This will allow
lots of ad hoc checking/validation to be removed throughout
the code.
Each command definition can also be routed to a specific
function to implement it. The function is associated with
an enum value for the command definition (generated from
the ID string.) These per-command-definition implementation
functions have not yet been created, so all commands
currently fall back to the existing per-command-name
implementation functions.
Using per-command-definition functions will allow lots of
code to be removed which tries to figure out what the
command is meant to do. This is currently based on ad hoc
and complicated option analysis. When using the new
functions, what the command is doing is already known
from the associated command definition.
When lvm commands are executed in lvm shell, we cover the whole lvm
command execution within this shell now. That means, all messages logged
and status caught during each command execution is now recorded in the
log report, including overall command's return code.
With patches that will follow, this will make it possible to widen log
report coverage when commands are executed from lvm shell so the amount
of messages that may end up in stderr/stdout instead of log report are
minimized.
Previously, a command sent lvmetad new VG metadata in vg_commit().
In vg_commit(), devices are suspended, so any memory allocation
done by the command while sending to lvmetad, or by lvmetad while
updating its cache could deadlock if memory reclaim was triggered.
Now lvmetad is updated in unlock_vg(), after devices are resumed.
The new method for updating VG metadata in lvmetad is in two phases:
1. In vg_write(), before devices are suspended, the command sends
lvmetad a short message ("set_vg_info") telling it what the new
VG seqno will be. lvmetad sees that the seqno is newer than
the seqno of its cached VG, so it sets the INVALID flag for the
cached VG. If sending the message to lvmetad fails, the command
fails before the metadata is committed and the change is not made.
If sending the message succeeds, vg_commit() is called.
2. In unlock_vg(), after devices are resumed, the command sends
lvmetad the standard vg_update message with the new metadata.
lvmetad sees that the seqno in the new metadata matches the
seqno it saved from set_vg_info, and knows it has the latest
copy, so it clears the INVALID flag for the cached VG.
If a command fails between 1 and 2 (after committing the VG on disk,
but before sending lvmetad the new metadata), the cached VG retains
the INVALID flag in lvmetad. A subsequent command will read the
cached VG from lvmetad, see the INVALID flag, ignore the cached
copy, read the VG from disk instead, update the lvmetad copy
with the latest copy from disk, (this clears the INVALID flag
in lvmetad), and use the correct VG metadata for the command.
(This INVALID mechanism already existed for use by lvmlockd.)
Simplify code around _do_get_report_selection - remove "expected_idxs[]"
argument which is superfluous and add "allow_single" switch instead to
allow for recognition of "--configreport <report_name> -S" as well as
single "-S" if needed.
Null pointer dereferences (FORWARD_NULL) /safe/guest2/covscan/LVM2.2.02.158/tools/reporter.c: 961 in _do_report_get_selection()
Null pointer dereferences (FORWARD_NULL) Dereferencing null pointer "single_args".
Uninitialized variables (UNINIT) /safe/guest2/covscan/LVM2.2.02.158/tools/toollib.c: 3520 in _process_pvs_in_vgs()
Uninitialized variables (UNINIT) Using uninitialized value "do_report_ret_code".
Null pointer dereferences (REVERSE_INULL) /safe/guest2/covscan/LVM2.2.02.158/libdm/libdm-report.c: 4745 in dm_report_output()
Null pointer dereferences (REVERSE_INULL) Null-checking "rh" suggests that it may be null, but it has already been dereferenced on all paths leading to the check.
Incorrect expression (MISSING_COMMA) /safe/guest2/covscan/LVM2.2.02.158/lib/log/log.c: 280 in _get_log_level_name()
Incorrect expression (MISSING_COMMA) In the initialization of "log_level_names", a suspicious concatenated string ""noticeinfo"" is produced.
Null pointer dereferences (FORWARD_NULL) /safe/guest2/covscan/LVM2.2.02.158/tools/reporter.c: 816 in_get_report_options()
Null pointer dereferences (FORWARD_NULL) Comparing "mem" to null implies that "mem" might be null.
This patch adds structures and functions to reroute error and warning
logs to log report, if it's set.
There are 5 new functions:
- log_set_report
Set log report where logging will be rerouted.
- log_set_report_context
Set context globally so any report_cmdlog call will use it.
- log_set_report_object_type
Set object type globally so any report_cmdlog call will use it.
- log_set_report_object_name_and_id
Set object ID and name globally so any report_cmdlog call will use it.
- log_set_report_object_group_and_group_id
Set object group ID and name globally so any report_cmdlog call will use it.
These functions will be called during LVM command processing so any logs
which are rerouted to log report contain proper information about current
processing state.
The lvm fullreport works per VG and as such, the vg, lv, pv, seg and
pvseg subreport is done for each VG. However, if the PV is not part of
any VG yet, we still want to display pv and pvseg subreports for these
"orphan" PVs - so enable this for lvm fullreport's process_each_vg call.
If there's parent processing handle, we don't need to create completely
new report group and status report - we'll just reuse the one already
initialized for the parent.
Currently, the situation where this matter is when doing internal report
to do the selection for processing commands where we have parent processing
handle for the command itself and processing handle for the selection
part (that is selection for non-reporting tools).
Wire up report group creation with log report in struct
processing_handle and call report_format_init during processing handle
initialization (init_processing_handle fn) and destroy it while
destroing processing handle (destroy_processing_handle fn).
This way, all the LVM command processing using processing handle
has access to log report via which the current command log
can be reported as items are processed.
A number of places are working on a specific dev when they
call lvmcache_info_from_pvid() to look up an info struct
based on a pvid. In those cases, pass the dev being used
to lvmcache_info_from_pvid(). When a dev is specified,
lvmcache_info_from_pvid() will verify that the cached
info it's using matches the dev being processed before
returning the info. Calling code will not mistakenly
get info for the wrong dev when duplicate devs exist.
This confusion was happening when scanning labels when
duplicate devs existed. label_read for the first dev
would add an info struct to lvmcache for that dev/pvid.
label_read for the second dev would see the pvid in
lvmcache from first dev, and mistakenly conclude that
the label_read from the second dev can be skipped
because it's already been done. By verifying that the
dev for the cached pvid matches the dev being read,
this mismatch is avoided and the label is actually read
from the second duplicate.
pvmove began processing tags unintentionally from commit,
6d7dc87cb pvmove: use toollib
pvmove works on a single PV, but tags can match multiple PVs.
If we allowed tags, but processed only the first matching PV,
then the resulting PV would be unpredictable.
Also, the current processing code does not allow us to simply
report an error and do nothing if more than one PV matches the tag,
because the command starts processing PVs as they are found,
so it's too late to do nothing if a second PV matches.
In the same way that process_each_vg() can be passed
a single VG name to process, also allow process_each_lv()
to be passed a single VG name and LV name to process.
This refactors the code for autoactivation. Previously,
as each PV was found, it would be sent to lvmetad, and
the VG would be autoactivated using a non-standard VG
processing function (the "activation_handler") called via
a function pointer from within the lvmetad notification path.
Now, any scanning that the command needs to do (scanning
only the named device args, or scanning all devices when
there are no args), is done first, before any activation
is attempted. During the scans, the VG names are saved.
After scanning is complete, process_each_vg is used to do
autoactivation of the saved VG names. This makes pvscan
activation much more similar to activation done with
vgchange or lvchange.
The separate autoactivate phase also means that if lvmetad
is disabled (either before or during the scan), the command
can continue with the activation step by simply not using
lvmetad and reverting to disk scanning to do the
activation.
Add support for active cache LV.
Handle --cachemode args validation during command line processing.
Rework some lvm2 internal to use lvm2 defined CACHE_MODE enums
indepently on libdm defines and use enum around the code instead
of passing and comparing strings.
Previously, duplicate PVs were processed as a side effect
of processing the "chosen" PV in lvmcache. The duplicate
PV would be hacked into lvmcache temporarily in place of
the chosen PV.
In the old way, we had to always process the "chosen" PV
device, even if a duplicate of it was named on the command
line. This meant we were processing a different device than
was asked for. This could be worked around by naming
multiple duplicate devs on the command line in which case
they were swapped in and out of lvmcache for processing.
Now, the duplicate devs are processed directly in their
own processing loop. This means we can remove the old
hacks related to processing dups as a side effect of
processing the chosen device. We can now simply process
the device that was named on the command line.
When the same PVID exists on two or more devices, one device
is preferred and used in the VG, and the others are duplicates
and are not used in the VG. The preferred device exists in
lvmcache as usual. The duplicates exist in a specical list
of unused duplicate devices.
The duplicate devs have the "d" attribute and the "duplicate"
reporting field displays "duplicate" for them.
'pvs' warns about duplicates, but the formal output only
includes the single preferred PV.
'pvs -a' has the same warnings, and the duplicate devs are
included in the output.
'pvs <path>' has the same warnings, and displays the named
device, whether it is preferred or a duplicate.
Wait to compare and choose alternate duplicate devices until
after all devices are scanned. During scanning, the first
duplicate dev is kept in lvmcache, and others are kept in a
new list (_found_duplicate_devs).
After all devices are scanned, compare all the duplicates
available for a given PVID and decide which is best.
If the dev used in lvmcache is changed, drop the old dev
from lvmcache entirely and rescan the replacement dev.
Previously the VG metadata from the old dev was kept in
lvmcache and only the dev was replaced.
A new config setting devices/allow_changes_with_duplicate_pvs
can be set to 0 which disallows modifying a VG or activating
LVs in it when the VG contains PVs with duplicate devices.
Set to 1 is the old behavior which allowed the VG to be
changed.
The logic for which of two devs is preferred has changed.
The primary goal is to choose a device that is currently
in use if the other isn't, e.g. by an active LV.
. prefer dev with fs mounted if the other doesn't, else
. prefer dev that is dm if the other isn't, else
. prefer dev in subsystem if the other isn't
If neither device is preferred by these rules, then don't
change devices in lvmcache, leaving the one that was found
first.
The previous logic for preferring a device was:
. prefer dev in subsystem if the other isn't, else
. prefer dev without holders if the other has holders, else
. prefer dev that is dm if the other isn't
Rather than doing repeated translations from name to
device when comparing args to existing PVs, do one
translation of the arg names and saving the device,
before checking existing PVs.
process_each_pv was doing:
1. lvmcache_seed_infos_from_lvmetad()
sends pv_list request to lvmetad.
2. get_vgnameids()
sends vg_list request to lvmetad.
3. _get_all_devices()
first calls lvmcache_seed_infos_from_lvmetad(),
which is a no-op if it's already been called.
Because get_vgnameids() does not use the information
from lvmcache_seed_infos_from_lvmetad(), it does not
need to be called prior to get_all_devices where
it is actually needed.
Commit 971ab733b7 ("thin: activation of
merging thin snapshot") also added an incorrect deactivation attempt
for non-thin LVs: find_snapshot(lv)->lv is not designed to be
activated and any attempt to deactivate it is incorrect.
With the recent conversion of pvcreate/pvremove to the
common toollib processing function, skipping in-use PVs
in _process_pvs_in_vg prevented them from being protected
as intended by the in-use flag.
The processing code for pvcreate/pvremove checks for the
in-use state itself and prevents using an in-use PV.
If a PV is skipped, it looks like an unused device and
is not protected from being used in pvcreate/pvremove.
When a command modifies a PV or VG, or changes the
activation state of an LV, it will send a dbus
notification when the command is finished. This
can be enabled/disabled with a config setting.
When processing LVs in a VG and when the -H|--history switch is used,
make process_each_lv_in_vg to iterate over historical volumes too.
For each historical LV, we use dummy struct logical_volume instance with
the "this_glv" reference set to a wrapper over proper struct
historical_logical_volume representation. This makes it possible to process
historical LVs just like normal live LVs (though a dummy one without any
segments and all the other fields zeroed and blank) and it also allows
for using all historical LV related information via lv->this_glv->historical
reference.
One can use a simple call to lv_is_historical to make a difference between
live and historical LV in all the code that is called by process_each_* fns.
This patch adds "include_historical_lvs" field to struct cmd_context to
make it possible for the command to switch between original funcionality
where no historical LVs are processed and functionality where historical
LVs are taken into account (and reported or processed further). The switch
between these modes is done using the '-H|--history' switch on command
line.
The include_historical_lvs state is then passed to process_each_* fns
using the "include_historical_lvs" field within struct processing_handle.
"pvcreate_each_params" was a temporary name used
to transition from the old "pvcreate_params".
Remove the old pvcreate_params struct and rename the
new pvcreate_each_params struct to pvcreate_params.
Rename various pvcreate_each_params terms to simply
pvcreate_params.
This is common code for handling PV create/remove
that can be shared by pvcreate/vgcreate/vgextend/pvremove.
This does not change any commands to use the new code.
- Pull out the hidden equivalent of process_each_pv
into an actual top level process_each_pv.
- Pull the prompts to the top level, and do not
run any prompts while locks are held.
The orphan lock is reacquired after any prompts are
done, and the devices being created are checked for
any change made while the lock was not held.
Previously, pvcreate_vol() was the shared function for
creating a PV for pvcreate, vgcreate, vgextend.
Now, it will be toollib function pvcreate_each_device().
pvcreate_vol() was called effectively as a helper, from
within vgcreate and vgextend code paths.
pvcreate_each_device() will be called at the same level
as other process_each functions.
One of the main problems with pvcreate_vol() is that
it included a hidden equivalent of process_each_pv for
each device being created:
pvcreate_vol() -> _pvcreate_check() ->
find_pv_by_name() -> get_pvs() ->
get_pvs_internal() -> _get_pvs() -> get_vgids() ->
/* equivalent to process_each_pv */
dm_list_iterate_items(vgids)
vg = vg_read_internal()
dm_list_iterate_items(&vg->pvs)
pvcreate_each_device() reorganizes the code so that
each-VG-each-PV loop is done once, and uses the standard
process_each_pv function at the top level of the function.
If we know that a PV belongs to some VG and we're missing metadata
(because we have only those PV(s) from VG present in the system that
don't have metadata areas), we should skip such PV when processing
under system ID.
This is because we know that the PV belongs to some VG, but we
really can't decide whether it matches system ID unless the VG
metadata is present again.
If we know that the PV is orphan, meaning there's at least one MDA on
that PV which does not reference any VG and at the same time there's
PV_EXT_USED flag set, we're certainly in an inconsistent state and we
need to fix this.
For example, such situation can happen during vgremove/vgreduce if we
removed/reduced the VG, but we haven't written PV headers yet because
vgremove stopped abruptly for whatever reason just before writing new
PV headers with updated state, including PV extension flags (and so the
PV_EXT_USED flag).
However, in case the PV has no MDAs at all, we can't double-check
whether the PV_EXT_USED is correct or not - if that PV is marked
as used, it's either:
- really used (but other disks with MDAs are missing)
- or the error state as described above is hit
User needs to overwrite the PV header directly if it's really clear
the PV having no MDAs does not belong to any VG and at the same time
it's still marked as being in use (pvcreate -ff <dev_name> will fix this).
For example - /dev/sda here has 1 MDA, orphan and is incorrectly marked
with PV_EXT_USED flag:
$ pvs --binary -o+pv_in_use
WARNING: Found inconsistent standalone Physical Volumes.
WARNING: Repairing flag incorrectly marking Physical Volume /dev/sda as used.
PV VG Fmt Attr PSize PFree InUse
/dev/sda lvm2 --- 128.00m 128.00m 0
This is a hotfix for a bug introduced in
6d7dc87cb3.
The bug description: First we allocate memory for
processing handle (at an address 1) then we
allocate some memory on the same pool for later use
in pvmove_poll function inside the process_each_pv
function (at an address 2). After we jump out of
process_each_pv we called destroy_processing_handle.
As a result of destroying the handle memory pool could
deallocate all memory at address 1 or higher. The
pvmove_poll function tried to copy a memory allocated
at address 2 that could be returned to the system.
If it was so it led to segfault.
We need to rethink proper fix but in the same time
cmd->mem pool is recreated per each lvm command so
this should not cause problems even when we run
multiple commands in lvm shell.
A valgrind snapshot of the corruption:
Invalid read of size 1
at 0x4C29F92: strlen (mc_replace_strmem.c:403)
by 0x5495F2E: dm_pool_strdup (pool.c:51)
by 0x1592A7: _create_id (pvmove.c:774)
by 0x159409: pvmove_poll (pvmove.c:796)
by 0x1599E3: pvmove (pvmove.c:931)
by 0x15105B: lvm_run_command (lvmcmdline.c:1655)
by 0x1523C3: lvm2_main (lvmcmdline.c:2121)
by 0x1754F3: main (lvm.c:22)
Address 0xf15df8a is 138 bytes inside a block of size 8,192 free'd
at 0x4C28430: free (vg_replace_malloc.c:446)
by 0x5494E73: dm_free_wrapper (dbg_malloc.c:357)
by 0x5495DE2: _free_chunk (pool-fast.c:318)
by 0x549561C: dm_pool_free (pool-fast.c:151)
by 0x164451: destroy_processing_handle (toollib.c:1837)
by 0x1598C1: pvmove (pvmove.c:903)
by 0x15105B: lvm_run_command (lvmcmdline.c:1655)
by 0x1523C3: lvm2_main (lvmcmdline.c:2121)
by 0x1754F3: main (lvm.c:22)
Fix regression caused by c9f021de0b.
This commit actually transfered real-action (e.g. device removal)
into the next loop which has however missed to check for break.
So add check for break also there.
When creating a list in 'context of command' - use proper mempool.
vg->vgmem is mempool related to VG metadata - and can be eventually
locked read-only when VG struct is shared.
The extent size must fits all blocks in 4294967295 sectors
(in 512b units) this is 1/2 KiB less then 2TiB.
So while previous statement 'suggested' 2TiB is still acceptable value,
make it clear it's not.
As now we support any multiples of 128KB as extent size -
values like 2047G will still 'flow-in' otherwise the largest power-of-2
supported value is 1TiB.
With 1TiB user needs 8388608 extents for 8EiB device.
(FYI such device is already unusable with todays glibc-2.22.90-27)
4GiB extent size is currently the smallest extent size which allows
a user to create 8EiB devices (with 2GiB it's less then 8EiB).
TODO: lvm2 may possibly print amount of 'lost/unused space' on a PV,
since using such ridiculously sized extent size may result in huge
space being left unaccessible.
Add a comment in _process_pvs_in_vg() to document the
place where there have been problems with processing
PVs twice.
For a while we had a hacky workaround here where we'd
skip processing a PV if its device wasn't found in
all_devices (and !is_missing_pv since we want to
process PVs with missing devices.). That workaround
was removed in commit 5cd4d46f because it was no
longer needed.
The workaround had originally been needed to prevent
a device from being processed twice when the PV had
no MDAs -- it would be processed once in its real VG
and then the workaround would prevent it from being
processed a second time in the orphan VG.
Wrongly appearing as an orphan likely happened because
lvmcache would consider the no-MDA PV an orphan unless
the real VG holding that PV was also in lvmcache.
This issue is also mentioned in pvchange where holding
the global lock allows VGs to remain in lvmcache so
PVs with 0 mdas are not considered orphans.
The workaround in _process_pvs_in_vg() was originally
intended for reporting commands, not for pvchange.
But, it was accidentally helping pvchange also because
the method described by the pvchange global lock
comment had been subverted by commit 80f4b4b8.
Commit 80f4b4b8 was found to be unnecessary, and was
reverted in commit e710bac0. This restored the
intended global lock lvmcache effect to pvchange, and
it no longer relied on the workaround in toollib.
The problem addressed by this workaround no longer
seems to exist, so remove it. PVs with no mdas
no longer appear in both their actual VG and in
the orphan VG.
Use process_each_vg() to lock and read the old VG,
and then call the main vgrename code.
When real VG names are used (not a UUID in place of the
old name), the command still pre-locks the new name
(when strcmp wants it locked first), before calling
process_each_vg on the old name.
In the case where the old name is replaced with a UUID,
process_each_vg now translates that UUID into the real
VG name, which it locks and reads. In this case, we
cannot do pre-locking to maintain lock ordering because
the old name is unknown. So, in this case the strcmp
based lock ordering is suppressed and the old name is
always locked first. This opens a remote chance for
lock ordering conflict between racing vgrenames between
two names where one or both commands use the UUID.
Also always clear the internal lvmcache after rescanning, and
reinstate a test for --trustcache so that 'pvs --trustcache'
(for example) avoids rescanning.
Before commit c1f246fedf,
_get_all_devices() did a full device scan before
get_vgnameids() was called. The full scan in
_get_all_devices() is from calling dev_iter_create(f, 1).
The '1' arg forces a full scan.
By doing a full scan in _get_all_devices(), new devices
were added to dev-cache before get_vgnameids() began
scanning labels. So, labels would be read from new devices.
(e.g. by the first 'pvs' command after the new device appeared.)
After that commit, _get_all_devices() was called
after get_vgnameids() was finished scanning labels.
So, new devices would be missed while scanning labels.
When _get_all_devices() saw the new devices (after
labels were scanned), those devices were added to
the .cache file. This meant that the second 'pvs'
command would see the devices because they would be
in .cache.
Now, the full device scan is factored out of
_get_all_devices() and called by itself at the
start of the command so that new devices will
be known before get_vgnameids() scans labels.
In general, --select should be used to specify a VG by UUID,
but vgrename already allows a uuid to be substituted for
the name, so continue to allow it in that case.
If the VG arg from the command line does not match the
name of any known VGs, then check if the arg looks like
a UUID. If it's a valid UUID, then compare it to the
UUID of known VGs. If it matches the UUID of a known VG,
then process that VG.
Pass the single vgname as a new process_each_vg arg
instead of setting a cmd flag to tell process_each_vg
to take only the first vgname arg from argv.
Other commands with different argv formats will be
able to use it this way.
If two different VGs with the same name exist on the system,
a command that just specifies that ambiguous name will fail
with a new error:
$ vgs -o name,uuid
...
foo qyUS65-vn32-TuKs-a8yF-wfeQ-7DkF-Fds0uf
foo vfhKCP-mpc7-KLLL-Uh08-4xPG-zLNR-4cnxJX
$ lvs foo
Multiple VGs found with the same name: foo
Use the --select option with VG UUID (vg_uuid).
$ vgremove foo
Multiple VGs found with the same name: foo
Use the --select option with VG UUID (vg_uuid).
$ lvs -S vg_uuid=qyUS65-vn32-TuKs-a8yF-wfeQ-7DkF-Fds0uf
lv1 foo ...
This is implemented for process_each_vg/lv, and works
with or without lvmetad. It does not work for commands
that do not use process_each.
This change includes one exception to the behavior shown
above. If one of the VGs is foreign, and the other is not,
then the command assumes that the intended VG is the local
one and uses it.
This makes process_each_vg/lv always use the list of
vgnames on the system. When specific VGs are named on
the command line, the corresponding entries from
vgnameids_on_system are moved to vgnameids_to_process.
Previously, when specific VGs were named on the command
line, the vgnameids_on_system list was not created, and
vgnameids_to_process was created from the arg_vgnames
list (which is only names, without vgids).
Now, vgnameids_on_system is always created, and entries
are moved from that list to vgnameids_to_process -- either
some (when arg_vgnames specifies only some), or all (when
the command is processing all VGs, or needs to look at
all VGs for checking tags/selection).
This change adds one new lvmetad lookup (vg_list) to a
command that specifies VG names. It adds no new work
for other commands, e.g. non-lvmetad commands, or
commands that look at all VGs.
When using lvmetad, 'lvs foo' previously sent one
request to lvmetad: 'vg_lookup foo'.
Now, 'lvs foo' sends two requests to lvmetad:
'vg_list' and 'vg_lookup foo <uuid>'.
(The lookup can now always include the uuid in the request
because the initial vg_list contains name/vgid pairs.)
The recent addition to check for PVs that were
missed during the first iteration of processing
was unintentionally catching duplicate PVs because
duplicates were not removed from the all_devices
list when the primary dev was processed.
Also change a message from warn back to verbose.
If a VG is removed between the time that 'vgs'
or 'lvs' (with no args) creates the list of VGs
and the time that it reads the VG to process it,
then ignore the removed VG; don't report an error
that it could not be found, since it wasn't named
by the command.
PVs could be missing from the 'pvs' output if
their VG was removed at the same time that the
'pvs' command was run. To fix this:
1. If a VG is not found when processed, don't
silently skip the PVs in it, as is done when
the "skip" variable is set.
2. Repeat the VG search if some PVs are not
found on the first search through all VGs.
The second search uses a specific list of
PVs that were missed the first time.
testing:
/dev/sdb is a PV
/dev/sdd is a PV
/dev/sdg is not a PV
each test begins with:
vgcreate test /dev/sdb /dev/sdd
variations to test:
vgremove -f test & pvs
vgremove -f test & pvs -a
vgremove -f test & pvs /dev/sdb /dev/sdd
vgremove -f test & pvs /dev/sdg
vgremove -f test & pvs /dev/sdb /dev/sdg
The pvs command should always display /dev/sdb
and /dev/sdd, either as a part of VG test or not.
The pvs command should always print an error
indicating that /dev/sdg could not be found.
Commit 1a74171ca5 added
a check to ignore a VG that was FAILED_INCONSISTENT
if the command doesn't care if the VG is not found.
Remove that check because that case is never reached
by the current code.
The ONE_VGNAME_ARG was being passed and tested as
vg_read() flag but it's a cmd struct flag.
(It affects command arg processing in toollib,
not vg_read behavior. Flags related to command
processing are generally cmd struct flags, while
vg_read arg flags are generally related to vg_read
behavior.)
Running "vgremove -f VG & pvs" results in the pvs
command reporting that the VG is not found or is
inconsistent. If the VG is gone or being removed,
the pvs command should just skip it and not print
errors about it.
"Not found" is because the pvs command created the
list of VGs to process, including VG, then vgremove
removed the VG, then the pvs command came to to read
the VG to process it and did not find it.
An "inconsistent" error could be reported if vgremove
had only partially completed removing VG when pvs did
vg_read on the VG to process it, causing pvs to find
the VG in a partially-removed state.
This fix adds a flag that pvs uses to ignore a VG
that can't be read or is inconsistent.
If 'vgcreate --shared' finds both sanlock and dlm are running,
print a more accurate error message:
"Found multiple lock managers, select one with --lock-type."
When neither is running, we still print:
"Failed to detect a running lock manager to select lock type."
Using --lock-type sanlock|dlm implies --shared.
Using --shared selects lock type sanlock|dlm
(by choosing the one that's running.)
Using both --shared and --lock-type sanlock|dlm should
also be allowed (--shared is just redundant information.)
The unlock call will fail in expected and normal cases,
and should not cause the command to fail. (An actual
unlock in the lock manager should never fail.)
Add new profilable configurables:
allocation/cache_policy
allocation/cache_settings
and mark allocation/cache_pool_chunk_size as profilable as well.
Obsolete allocation/cache_pool_cachemode and
introduce new allocation/cache_mode instead.
Rename DEFAULT_CACHE_POOL_POLICY to DEFAULT_CACHE_POLICY.
When lvm is built without lvmlockd support, vgcreate using a
shared lock type would succeed and create a local VG (the
--shared option was effectively ignored). Make it fail.
Fix the same issue when using vgchange to change a VG to a
shared lock type.
Make the error messages consistent.
Keep policy name separate from policy settings and avoid
to mangling and demangling this string from same config tree.
Ensure policy_name is always defined.
There are two different failure conditions detected in
access_vg_lock_type() that should have different error
messages. This adds another failure flag so the two
cases can be distinguished to avoid printing a misleading
error message.
This prevents 'lvremove vgname' from attempting to remove the
hidden sanlock LV. Only vgremove should remove the hidden
sanlock LV holding the sanlock locks.
... Using uninitialized value "lockd_state" when calling "lockd_vg"
(even though lockd_vg assigns 0 to the lockd_state, but it looks at
previous state of lockd_state just before that so we need to have
that properly initialized!)
libdm/libdm-report.c:2934: uninit_use_in_call: Using uninitialized value "tm". Field "tm.tm_gmtoff" is uninitialized when calling "_get_final_time".
daemons/lvmlockd/lvmlockctl.c:273: uninit_use_in_call: Using uninitialized element of array "r_name" when calling "format_info_r_action". (just added FIXME as this looks unfinished?)
In process_each_{vg,lv,pv} when no vgname args are given,
the first step is to get a list of all vgid/vgname on the
system. This is exactly what lvmetad returns from a
vg_list request. The current code is doing a vg_lookup
on each VG after the vg_list and populating lvmcache with
the info for each VG. These preliminary vg_lookup's are
unnecessary, because they will be done again when the
processing functions call vg_read. This patch eliminates
the initial round of vg_lookup's, which can roughly cut in
half the number of lvmetad requests and save a lot of extra work.
Routines responsible for polling of in-progress pvmove, snapshot merge
or mirror conversion each used custom lookup functions to find vg and
lv involved in polling.
Especially pvmove used pvname to lookup pvmove in-progress. The future
lvmpolld will poll each operation by vg/lv name (internally by lvid).
Also there're plans to make pvmove able to move non-overlaping ranges
of extents instead of single PVs as of now. This would also require
to identify the opertion in different manner.
The poll_operation_id structure together with daemon_parms structure they
identify unambiguously the polling task.
With use_lvmetad=0, duplicate PVs /dev/loop0 and /dev/loop1,
where in this example, /dev/loop1 is the cached device
referenced by pv->dev, the command 'pvs /dev/loop0' reports:
Failed to find physical volume "/dev/loop0".
This is because the duplicate PV detection by pvid is
not working because _get_all_devices() is not setting
any dev->pvid for any entries. This is because the
pvid information has not yet been saved in lvmcache.
This is fixed by calling _get_vgnameids_on_system()
before _get_all_devices(), which has the effect of
caching the necessary pvid information.
With this fix, running pvs /dev/loop0, or pvs /dev/loop1,
produces no error and one line of output for the PV (the
device printed is the one cached in pv->dev, in this
example /dev/loop1.)
Running 'pvs /dev/loop0 /dev/loop1' produces no error
and two lines of output, with each device displayed
on one of the lines.
Running 'pvs -a' shows two PVs, one with loop0 and one
with loop1, and both shown as a member of the same VG.
Running 'pvs' shows only one of the duplicate PVs,
and that shows the device cached in pv->dev (loop1).
The above output is what the duplicate handling code
was previously designed to output in commits:
b64da4d8b5 toollib: search for duplicate PVs only when needed
3a7c47af0e toollib: pvs -a should display VG name for each duplicate PV
57d74a45a0 toollib: override the PV device with duplicates
c1f246fedf toollib: handle duplicate pvs in process_in_pv
As a further step after this, we may choose to change
some of those.
For all of these commands, a warning is printed about
the existence of the duplicate PVs:
Found duplicate PV ...: using /dev/loop1 not /dev/loop0
sharing connection between parent command and background
processes spawned from parent could lead to occasional failures
due to unexpected corruption in daemon responses sent to either child
or a parent.
lvmetad issued warning about duplicate config values in request.
LVM commands occasionaly failed w/ internal error after receving
corrupted response.
lvmetad connection is renewed when needed after explicit disconnect
in child
spawning a background polling from within the lv_change_activate
fn went to two problems:
1) vgchange should not spawn any background polling until after
the whole activation process for a VG is finished. Otherwise
it could lead to a duplicite request for spawning background
polling. This statement was alredy true with one exception of
mirror up-conversion polling (fixed by this commit).
2) due to current conditions in lv_change_activate lvchange cmd
couldn't start background polling for pvmove LVs if such LV was
about to get activated by the command in the same time.
This commit however doesn't alter the lvchange cmd so that it works same as
vgchange with regard to not to spawn duplicate background pollings per
unique LV.
Do not keep dangling LVs if they're removed from the vg->lvs list and
move them to vg->removed_lvs instead (this is actually similar to already
existing vg->removed_pvs list, just it's for LVs now).
Once we have this vg->removed_lvs list indexed so it's possible to
do lookups for LVs quickly, we can remove the LV_REMOVED flag as
that one won't be needed anymore - instead of checking the flag,
we can directly check the vg->removed_lvs list if the LV is present
there or not and to say if the LV is removed or not then. For now,
we don't have this index, but it may be implemented in the future.
This avoids a problem in which we're using selection on LV list - we
need to do the selection on initial state and not on any intermediary
state as we process LVs one by one - some of the relations among LVs
can be gone during this processing.
For example, processing one LV can cause the other LVs to lose the
relation to this LV and hence they're not selectable anymore with
the original selection criteria as it would be if we did selection
on inital state. A perfect example is with thin snapshots:
$ lvs -o lv_name,origin,layout,role vg
LV Origin Layout Role
lvol1 thin,sparse public,origin,thinorigin,multithinorigin
lvol2 lvol1 thin,sparse public,snapshot,thinsnapshot
lvol3 lvol1 thin,sparse public,snapshot,thinsnapshot
pool thin,pool private
$ lvremove -ff -S 'lv_name=lvol1 || origin=lvol1'
Logical volume "lvol1" successfully removed
The lvremove command above was supposed to remove lvol1 as well as
all its snapshots which have origin=lvol1. It failed to do so, because
once we removed the origin lvol1, the lvol2 and lvol3 which were
snapshots before are not snapshots anymore - the relations change
as we're processing these LVs one by one.
If we do the selection first and then execute any concrete actions on
these LVs (which is what this patch does), the behaviour is correct
then - the selection is done on the *initial state*:
$ lvremove -ff -S 'lv_name=lvol1 || origin=lvol1'
Logical volume "lvol1" successfully removed
Logical volume "lvol2" successfully removed
Logical volume "lvol3" successfully removed
Similarly for all the other situations in which relations among
LVs are being changed by processing the LVs one by one.
This patch also introduces LV_REMOVED internal LV status flag
to mark removed LVs so they're not processed further when we
iterate over collected list of LVs to be processed.
Previously, when we iterated directly over vg->lvs list to
process the LVs, we relied on the fact that once the LV is removed,
it is also removed from the vg->lvs list we're iterating over.
But that was incorrect as we shouldn't remove LVs from the list
during one iteration while we're iterating over that exact list
(dm_list_iterate_items safe can handle only one removal at
one iteration anyway, so it can't be used here).
In log messages refer to it as system ID (not System ID).
Do not put quotes around the system_id string when printing.
On the command line use systemid.
In code, metadata, and config files use system_id.
In lvmsystemid refer to the concept/entity as system_id.
Commands that can never use foreign VGs begin with
cmd->error_foreign_vgs = 1. This tells the vg_read
lib layer to print an error as soon as a foreign VG
is read.
The toollib process_each layer also prints an error if a
foreign VG is read, but is more selective about it. It
won't print an error if the command did not explicitly
name the foreign VG. We want to silently ignore foreign VGs
unless a command attempts to use one explicitly.
So, foreign VG errors are printed from two different layers:
vg_read (lower layer) and process_each (upper layer).
Commands that use toollib process_each, only want errors from
the process_each layer, not from both layers. So, process_each
disables the lower layer vg_read error message by setting
error_foreign_vgs = 0.
Commands that do not use toollib process_each, want errors
from the vg_read layer, otherwise they would get no error
message. The original cmd->error_foreign_vgs setting
enables this error.
(Commands that are allowed to operate on foreign VGs always
begin with cmd->error_foreign_vgs = 0, and all the commands
in this group use toollib process_each with the selective
error reporting.)
When checking whether the system ID permits access to a VG, check for
each permitted situation first, and only then issue the appropriate
error message. Always issue a message for now. (We'll try to
suppress some of those later when the VG concerned wasn't explicitly
requested.)
Add more messages to try to ensure every return code is checked and
every error path (and only an error path) contains a log_error().
Add self-correction to vgchange -c to deal with situations where
the cluster state and system ID state are out-of-sync (e.g. if
old tools were used).
(This reverts patch #d95c6154)
Filter complete device list through full_filter unconditionally when
we're getting the list of *all* devices even in case we're interested
only in fraction of those devices - the PVs, not the other devices
which are not PVs yet (e.g. pvs vs. pvs -a).
We need to do this full filtering whenever we're handling *complete*
list of devices, we need to be safe here, mainly if there are any
future changes and we'd forgot to change to use proper filtering then.
Also properly preventing duplicates if there are any block subsystem
components used (mpath, MD ...).
Thing here is that (under use_lvmetad=1), cmd->filter can be used
only if we're sure that the list of devices we're filtering contains
only PVs. We have to use cmd->full_filter otherwise (like it is in
case of _get_all_devices fn which acquires complete list of devices,
no matter if it is a PV or not).
Of course, cmd->full_filter is more extensive than cmd->filter
which is only a subset of full_filter.
We could optimize this in a way that if we're interested in PVs only
during process_each_pv processing (e.g. using pvs in contrast to pvs -a),
we'd get the list of PV devices directly from lvmetad from the
lvmcache_seed_infos_from_lvmetad fn call which currently updates
lvmcache only. We'd add an additional output arg for this fn to get
the list of PV devices directly in addition, without a need to iterate
over all devices which include non-PVs which we're not interested in
anyway, hence we could use only cmd->filter, not the cmd->full_filter.
So the code would look something like this:
static int _get_all_devices(....)
{
struct device_id_list *dil;
if (interested_in_pvs_only)
lvmcache_seed_infos_from_lvmetad(cmd, &dil); /* new "dil" arg */
/* the "dil" list would be filtered through cmd->filter inside lvmcache_seed_infos_from_lvmetad */
else {
lvmcache_seed_infos_from_lvmetad(cmd, NULL);
dev_iter_create(cmd->full_filter)
while (dev = dev_iter_get ...) {
dm_list_add(all_devices, &dil->list);
}
}
}
It's cleaner this way - do not mix static and dynamic
(init_processing_handle) initializers. Use the dynamic one everywhere.
This makes it easier to manage the code - there are no "exceptions"
then and we don't need to take care about two ways of initializing the
same thing - just use one common initializer throughout and it's clear.
Also, add more comments, mainly in the report_for_selection fn explaining
what is being done and why with respect to the processing_handle and
selection_handle.
We still need to get the list as the calls underneath process_each_pv
rely on this list. But still keep the change related to the filters -
if we're processing all devices, we need to use cmd->full_filter.
If we're processing only PVs, we can use cmd->filter only to save
some time which would be spent in filtering code.
When lvmetad is used and at the same time we're getting list of all
PV-capable devices, we can't use cmd->filter (which is used to filter
out lvmetad responses - so we're sure that the devices are PVs already).
To get the list of PV-capable devices, we're bypassing lvmetad (since
lvmetad only caches PVs, not all the other devices which are not PVs).
For this reason, we have to use the "full_filter" filter chain (just
like we do when we're running without lvmetad).
Example scenario:
- sdo and sdp components of MD device md0
- sdq, sdr and sds components of mpatha multipath device
- mpatha multipath device partitioned
- vda device partitioned
=> sdo,sdp,sdr,sds, mpatha and vda should be filtered!
$ lsblk -o NAME,TYPE
NAME TYPE
sdn disk
sdo disk
`-md0 raid0
sdp disk
`-md0 raid0
sdq disk
`-mpatha mpath
`-mpatha1 part
sdr disk
`-mpatha mpath
`-mpatha1 part
sds disk
`-mpatha mpath
`-mpatha1 part
vda disk
|-vda1 part
`-vda2 part
|-fedora-swap lvm
`-fedora-root lvm
Before this patch:
==================
use_lvmetad=0 (correct behaviour!)
$ pvs -a
PV VG Fmt Attr PSize PFree
/dev/fedora/root --- 0 0
/dev/fedora/swap --- 0 0
/dev/mapper/mpatha1 --- 0 0
/dev/md0 --- 0 0
/dev/sdn --- 0 0
/dev/vda1 --- 0 0
/dev/vda2 fedora lvm2 a-- 9.51g 0
use_lvmetad=1 (incorrect behaviour - sdo,sdp,sdq,sdr,sds and mpatha not filtered!)
$ pvs -a
PV VG Fmt Attr PSize PFree
/dev/fedora/root --- 0 0
/dev/fedora/swap --- 0 0
/dev/mapper/mpatha --- 0 0
/dev/mapper/mpatha1 --- 0 0
/dev/md0 --- 0 0
/dev/sdn --- 0 0
/dev/sdo --- 0 0
/dev/sdp --- 0 0
/dev/sdq --- 0 0
/dev/sdr --- 0 0
/dev/sds --- 0 0
/dev/vda --- 0 0
/dev/vda1 --- 0 0
/dev/vda2 fedora lvm2 a-- 9.51g 0
With this patch applied:
========================
use_lvmetad=1
$ pvs -a
PV VG Fmt Attr PSize PFree
/dev/fedora/root --- 0 0
/dev/fedora/swap --- 0 0
/dev/mapper/mpatha1 --- 0 0
/dev/md0 --- 0 0
/dev/sdn --- 0 0
/dev/vda1 --- 0 0
/dev/vda2 fedora lvm2 a-- 9.51g 0
List of all devices is only needed if we want to process devices
which are not PVs (e.g. pvs -a). But if this is not the case, it's
useless to get the list of all devices and then discard it without
any use, which is exactly what happened in process_each_pv where
the code was never reached and the list was unused if we were
processing just PVs, not all PV-capable devices:
int process_each_pv(...)
{
...
process_all_devices = process_all_pvs &&
(cmd->command->flags & ENABLE_ALL_DEVS) &&
arg_count(cmd, all_ARG);
...
/*
* If the caller wants to process all devices (not just PVs), then all PVs
* from all VGs are processed first, removing them from all_devices. Then
* any devs remaining in all_devices are processed.
*/
_get_all_devices(cmd, &all_devices);
...
ret = _process_pvs_in_vgs(...);
...
if (!process_all_devices)
goto out;
ret = _process_device_list(cmd, &all_devices, handle, process_single_pv);
...
}
This patch adds missing check for "process_all_devices" and it gets the
list of all (including non-PV) devices only if needed:
This is a followup patch for previous patchset that enables selection in
process_each_* fns to fix an issue where field prefixes are not
automatically used for fields in selection criteria.
Use initial report type that matches the intention of each process_each_* functions:
- _process_pvs_in_vg - PVS
- process_each_vg - VGS
- process_each_lv and process_each_lv_in_vg - LVS
This is not normally needed for the selection handle init, BUT we would
miss the field prefix matching, e.g.
lvchange -ay -S 'name=lvol0'
The "name" above would not work if we didn't initialize reporting with
the LVS type at its start. If we pass proper init type, reporting code
can deduce the prefix automatically ("lv_name" in this case).
This report type is then changed further based on what selection criteria we
have. When doing pure selection, not report output, the final report type
is purely based on combination of this initial report type and report types
of the fields used in selection criteria.
The report_for_selection does the actual "reporting for selection only".
The selection status will be saved in struct selection_handle's "selected"
variable.
This applies to:
- process_each_lv_in_vg - the VG is selected only if at least one of its LVs is selected
- process_each_segment_in_lv - the LV is selected only if at least one of its LV segments is selected
- process_each_pv_in_vg - the VG is selected only if at least one of its PVs is selected
- process_each_segment_in_pv - the PV is selected only if at least one of its PV segments is selected
So this patch causes the selection result to be properly propagated up to callers.
Call _init_processing_handle, _init_selection_handle and
_destroy_processing_handle in process_each_* and related functions to
set up and destroy handles used while processing items.
The init_processing_handle, init_selection_handle and
destroy_processing_handle are helper functions that allocate and
initialize the handles used when processing items in process_each_*
and related functions.
The "struct processing_handle" contains handles to drive the selection/matching
so pass it to the _select_match_* functions which are entry points to the
selection mechanism used in process_each_* and related functions.
This is revised and edited version of former Dave Teigland's patch which
provided starting point for all the select support in process_each_* fns.
This patch replaces "void *handle" with "struct processing_handle *handle"
in process_each_*, process_single_* and related functions.
The struct processing_handle consists of two handles inside now:
- the "struct selection_handle *selection_handle" used for
applying selection criteria while processing process_each_*,
process_single_* and related functions (patches using this
logic will follow)
- the "void* custom_handle" (this is actually the original handle
used before this patch - a pointer to custom data passed into
process_each_*, process_single_* and related functions).
A full search for duplicate PVs in the case of pvs -a
is only necessary when duplicates have previously been
detected in lvmcache. Use a global variable from lvmcache
to indicate that duplicate PVs exist, so we can skip the
search for duplicates when none exist.
Previously, 'pvs -a' displayed the VG name for only the device
associated with the cached PV (pv->dev), and other duplicate
devices would have a blank VG name. This commit displays the
VG name for each of the duplicate devices. The cost of doing
this is not small: for each PV processed, the list of all
devices must be searched for duplicates.
When multiple duplicate devices are specified on the
command line, the PV is processed once for each of them,
but pv->dev is the device used each time.
This overrides the PV device to reflect the duplicate
device that was specified on the command line. This is
done by hacking the lvmcache to replace pv->dev with the
device of the duplicate being processed. (It would be
preferable to override pv->dev without munging the content
of the cache, and without sprinkling special cases throughout
the code.)
This override only applies when multiple duplicate devices are
specified on the command line. When only a single duplicate
device of pv->dev is specified, the priority is to display the
cached pv->dev, so pv->dev is not overridden by the named
duplicate device.
In the examples below, loop3 is the cached device referenced
by pv->dev, and is given priority for processing. Only after
loop3 is processed/displayed, will other duplicate devices
loop0/loop1 appear (when requested on the command line.)
With two duplicate devices, loop0 and loop3:
# pvs
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop3 not /dev/loop0
PV VG Fmt Attr PSize PFree
/dev/loop3 loopa lvm2 a-- 12.00m 12.00m
# pvs /dev/loop3
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop3 not /dev/loop0
PV VG Fmt Attr PSize PFree
/dev/loop3 loopa lvm2 a-- 12.00m 12.00m
# pvs /dev/loop0
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop3 not /dev/loop0
PV VG Fmt Attr PSize PFree
/dev/loop3 loopa lvm2 a-- 12.00m 12.00m
# pvs -o+dev_size /dev/loop0 /dev/loop3
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop3 not /dev/loop0
PV VG Fmt Attr PSize PFree DevSize
/dev/loop0 loopa lvm2 a-- 12.00m 12.00m 16.00m
/dev/loop3 loopa lvm2 a-- 12.00m 12.00m 32.00m
With three duplicate devices, loop0, loop1, loop3:
# pvs -o+dev_size
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop1 not /dev/loop0
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop3 not /dev/loop1
PV VG Fmt Attr PSize PFree DevSize
/dev/loop3 loopa lvm2 a-- 12.00m 12.00m 32.00m
# pvs -o+dev_size /dev/loop3
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop1 not /dev/loop0
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop3 not /dev/loop1
PV VG Fmt Attr PSize PFree DevSize
/dev/loop3 loopa lvm2 a-- 12.00m 12.00m 32.00m
# pvs -o+dev_size /dev/loop0
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop1 not /dev/loop0
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop3 not /dev/loop1
PV VG Fmt Attr PSize PFree DevSize
/dev/loop3 loopa lvm2 a-- 12.00m 12.00m 32.00m
# pvs -o+dev_size /dev/loop1
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop1 not /dev/loop0
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop3 not /dev/loop1
PV VG Fmt Attr PSize PFree DevSize
/dev/loop3 loopa lvm2 a-- 12.00m 12.00m 32.00m
# pvs -o+dev_size /dev/loop3 /dev/loop0
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop1 not /dev/loop0
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop3 not /dev/loop1
PV VG Fmt Attr PSize PFree DevSize
/dev/loop0 loopa lvm2 a-- 12.00m 12.00m 16.00m
/dev/loop3 loopa lvm2 a-- 12.00m 12.00m 32.00m
# pvs -o+dev_size /dev/loop3 /dev/loop1
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop1 not /dev/loop0
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop3 not /dev/loop1
PV VG Fmt Attr PSize PFree DevSize
/dev/loop1 loopa lvm2 a-- 12.00m 12.00m 32.00m
/dev/loop3 loopa lvm2 a-- 12.00m 12.00m 32.00m
# pvs -o+dev_size /dev/loop0 /dev/loop1
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop1 not /dev/loop0
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop3 not /dev/loop1
PV VG Fmt Attr PSize PFree DevSize
/dev/loop1 loopa lvm2 a-- 12.00m 12.00m 32.00m
/dev/loop3 loopa lvm2 a-- 12.00m 12.00m 32.00m
# pvs -o+dev_size /dev/loop0 /dev/loop1 /dev/loop3
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop1 not /dev/loop0
Found duplicate PV XhLbpVo0hmuwrMQLjfxuAvPFUFZqD4vr: using /dev/loop3 not /dev/loop1
PV VG Fmt Attr PSize PFree DevSize
/dev/loop0 loopa lvm2 a-- 12.00m 12.00m 16.00m
/dev/loop1 loopa lvm2 a-- 12.00m 12.00m 32.00m
/dev/loop3 loopa lvm2 a-- 12.00m 12.00m 32.00m
Processes a PV once for each time a device with its PV ID
exists on the command line.
This fixes a regression in the case where:
. devices /dev/sdA and /dev/sdB where clones (same PV ID)
. the cached VG references /dev/sdA
. before the regression, the command: pvs /dev/sdB
would display the cached device clone /dev/sdA
. after the regression, pvs /dev/sdB would display nothing,
causing vgimportclone /dev/sdB to fail.
. with this fix, pvs /dev/sdB displays /dev/sdA
Also, pvs /dev/sdA /dev/sdB will report two lines, one for each
device on the command line, but /dev/sdA is displayed for each.
This only works without lvmetad.
When processing PVs specified on the command line, the arg
name was being matched against pv_dev_name, which will not
always work:
- The PV specified on the command line could be an alias,
e.g. /dev/disk/by-id/...
- The PV specified on the command line could be any random
path to the device, e.g. /dev/../dev/sdb
To fix this, first resolve the named PV args to struct device's,
then iterate through the devices for processing.
The call to dm_config_destroy can derefence result->mem
while result is still NULL:
struct dm_config_tree *get_cachepolicy_params(struct cmd_context *cmd)
{
...
int ok = 0;
...
if (!(result = dm_config_flatten(current)))
goto_out;
...
ok = 1;
out:
if (!ok) {
dm_config_destroy(result)
...
}
...
}
ignore_vg now returns 0 for the FAILED_CLUSTERED case,
so all the ignore_vg 1 cases will return vg's with an
empty vg->pvs, so we do not need to iterate through
vg->pvs to remove the entries from the devices list.
Clean up whitespace problems in that area from the
previous commit.
- Fix problems with recent changes related to skipping in:
. _process_vgnameid_list
. _process_pvs_in_vgs
- Undo unnecessary changes to the code structure and readability.
- Preserve valid but minor changes:
. testing FAILED bit values in ignore_vg
. using "skip" value from ignore_vg instead of "ret" value
. applying the sigint check to the start of all loops
. setting stack backtrace when ECMD_PROCESSED is not returned,
i.e. apply the following pattern:
ret = process_foo();
if (ret != ECMD_PROCESSED)
stack;
if (ret > ret_max)
ret_max = ret;
Extend/fix d8923457b8 commit.
'skip'-ed VG is not holding any lock - so don't unlock such VG.
At the same time simplify the code around and relase VG at a single
place and unlock only not skiped and not ignored VGs.
Rework ignore_vg() API so it properly handles
multiple kind of vg_read_error() states.
Skip processing only otherwise valid VG.
Always return ECMD_FAILED when break is detected.
Check sigint_caught() in front of dm iterator loop.
Add stack for _process failing ret codes.
LVM2.2.02.112/tools/toollib.c:1991: leaked_storage: Variable "iter" going out of scope leaks the storage it points to.
LVM2.2.02.112/lib/filters/filter-usable.c:89: leaked_storage: Variable "f" going out of scope leaks the storage it points to.
LVM2.2.02.112/lib/activate/dev_manager.c:1874: leaked_handle: Handle variable "fd" going out of scope leaks the handle.
Let's use this function for more activations in the code.
'needs_exlusive' will enforce exlusive type for any given LV.
We may want to activate LV in exlusive mode, even when we know
the LV (as is) supports non-exlusive activation as well.
lvcreate -ay -> exclusive & local
lvcreate -aay -> exclusive & local
lvcreate -aly -> exclusive & local
lvcreate -aey -> exclusive (might be on any node).
Tool will use internal activation of unused cache pool to
clear metadata area before next use of cache-pool.
So allow to deactivation unused pool in case some error
case happend and we were not able to deactivation pool
right after metadata wipe.
Because of the recent change to process_each_pv(), the vg is always
provided when the pv is in a vg. is_pv(pv) means the pv is in a vg,
which means that the vg arg will not be NULL, which means the removed
block of code is not needed.
When we are given an existing LV name - it needs to be allowed
to pass in even restricted name as the LV could have existed
long before we introduced some new restriction on prefix/suffix.i
Fix the regression on name limits and drop restriction to be applied
on any existing LVs - only the new created LV names have to be
complient with current name restrictions.
FIXME: we are currently using restricted names incorrectly in few
other places - device_is_usable() skips restricted names,
and udev flags are also incorrectly set for restricted names
so these LVs are not getting links properly.
