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(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.
