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Disable until we have a proper fix for reshape space allocation,
switching it to begin/end of rimages and activation in the cluster.
Related: rhbz1448116
Related: rhbz1461526
Related: rhbz1448123
Commit 1fe4f80e45 in current version
introduced regression for a terminal user, as he could not enter 'n'
as answer. Add missing break for this case (No whats_new).
New tests to add checking for '100%' in-sync at start of "recover"
process (it shouldn't happen, but I've seen it before). Also,
check status over the whole cycle of various sync processes ("resync"
and "recover").
Enhance reporting code, so it does not need to do 'extra' ioctl to
get 'status' of normal raid and provide percentage directly.
When we have 'merging' snapshot into raid origin, we still need to get
this secondary number with extra status call - however, since 'raid'
is always a single segment LV - we may skip 'copy_percent' call as
we directly know the percent and also with better precision.
NOTE: for mirror we still base reported number on the percetage of
transferred extents which might get quite imprecisse if big size
of extent is used while volume itself is smaller as reporting jump
steps are much bigger the actual reported number provides.
2nd.NOTE: raid lvs line report already requires quite a few extra status
calls for the same device - but fix will be need slight code improval.
Current existing kernels reports status sometimes in weird form.
Instead of showing what is the exact progress, we need to estimate
this in-sync state from several surrounding states.
Main reason here is to never report 100% sync state for a raid device
which will be undergoing i.e. recovery.
Relative to last comit ddf2a1d656:
adjust the dm-raid target version to 1.12.0 which shows
mandatory kernel MD deadlock fixes related to reshaping
are presant in the kernel.
Related: rhbz1443999
First test in this file checks whether 'aa' is ever spotted during
a "recover" operation (it should not be). More tests should follow
in this file to look for oddities in status output - especially as
it relates to the sync_ratio, dev_health, and sync_action fields.
For the test clean-up, I was providing too many devices to the first
command - possibly allowing it to allocate in the wrong place. I was
also not providing a device for the second command - virtually ensuring
the test was not performing correctly at times.
This patch ensures that under normal conditions (i.e. not during repair
operations) that users are prevented from removing devices that would
cause data loss.
When a RAID1 is undergoing its initial sync, it is ok to remove all but
one of the images because they have all existed since creation and
contain all the data written since the array was created. OTOH, if the
RAID1 was created as a result of an up-convert from linear, it is very
important not to let the user remove the primary image (the source of
all the data). They should be allowed to remove any devices they want
and as many as they want as long as one original (primary) device is left
during a "recover" (aka up-convert).
This fixes bug 1461187 and includes the necessary regression tests.
Add the checks necessary to distiguish the state of a RAID when the primary
source for syncing fails during the "recover" process.
It has been possible to hit this condition before (like when converting from
2-way RAID1 to 3-way and having the first two devices die during the "recover"
process). However, this condition is now more likely since we treat linear ->
RAID1 conversions as "recover" now - so it is especially important we cleanly
handle this condition.
Previously, we were treating non-RAID to RAID up-converts as a "resync"
operation. (The most common example being 'linear -> RAID1'.) RAID to
RAID up-converts or rebuilds of specific RAID images are properly treated
as a "recover" operation.
Since we were treating some up-convert operations as "resync", it was
possible to have scenarios where data corruption or data loss were
possibilities if the RAID hadn't been able to sync completely before a
loss of the primary source devices. In order to ensure that the user took
the proper precautions in such scenarios, we required a '--force' option
to be present. Unfortuneately, the force option was rendered useless
because there was no way to distiguish the failure state of a potentially
destructive repair from a nominal one - making the '--force' option a
requirement for any RAID1 repair!
We now treat non-RAID to RAID up-converts properly as "recover" operations.
This eliminates the scenarios that can potentially cause data loss or
data corruption; and this eliminates the need for the '--force' requirement.
This patch removes the requirement to specify '--force' for RAID repairs.
Two of the sync actions performed by the kernel (aka MD runtime) are
"resync" and "recover". The "resync" refers to when an entirely new array
is going through the process of initializing (or resynchronizing after an
unexpected shutdown). The "recover" is the process of initializing a new
member device to the array. So, a brand new array with all new devices
will undergo "resync". An array with replaced or added sub-LVs will undergo
"recover".
These two states are treated very differently when failures happen. If any
device is lost or replaced while "resync", there are no worries. This is
because any writes created from the inception of the array have occurred to
all the devices and can be safely recovered. Even though non-initialized
portions will still be resync'ed with uninitialized data, it is ok. However,
if a pre-existing device is lost (aka, the original linear device in a
linear -> raid1 convert) during a "recover", data loss can be the result.
Thus, writes are errored by the kernel and recovery is halted. The failed
device must be restored or removed. This is the correct behavior.
Unfortunately, we were treating an up-convert from linear as a "resync"
when we should have been treating it as a "recover". This patch
removes the special case for linear upconvert. It allows each new image
sub-LV to be marked with a rebuild flag and treats the array as 'in-sync'.
This has the correct effect of causing the upconvert to be treated as a
"recover" rather than a "resync". There is no need to flag these two states
differently in LVM metadata, because they are already considered differently
by the kernel RAID metadata. (Any activation/deactivation will properly
resume the "recover" process and not a "resync" process.)
We make this behavior change based on the presense of dm-raid target
version 1.9.0+.
On conversion from raid10 to raid0 (takeover), all rmeta
devices and the rimage devices of mirrored stripes are
detached from the raid10 LV. The remaining rimage areas
are being shifted down into the slots of the detached
ones hence requiring renames to show proper _N suffix
sequences (e.g. 0,1,2,3 instead of 0,2,4,6). Only the
top-level raid10 LV has a cluster lock, not the detached
SubLVs thus their deactivation is impossible and e.g the
rename from *_rimage_6 to *_rimage_3 will fail. Fix by
activating exclusively before deactivating and removing.
Resolves: rhbz1448123
The file block count stored in the filemap_monitor was lazily
initialised at the time of the first check. This causes problems
in the case that the file has been truncated between this time and
the time the daemon started: the initial block count and current
block count match and the daemon fails to detect a change.
Separate the setting of the block count from the check and make a
call to update the value at the start of _dmfilemapd().
It's not an error to attempt to update regions from an fd that has
been truncated (or otherwise no longer has any allocated extents):
in this case, the call should remove all regions corresponding to
the group, and return an empty region table.
For proper usage of Cache kernel metadata format V2,
new cache_check tool is basically mandatory.
Print warning during configure time about this problem.
Prohibit activation of reshaping RaidLVs on incompatible
lvm2 runtime by storing e.g. 'raid5+RESHAPE' segment type
strings in the lvm2 metadata. Incompatible runtime not
supporting reshaping won't be able to activate those thus
avoiding potential data corruption.
Any new non-reshaping lvconvert command will reset the
segment type string from 'raid5+RESHAPE' to 'raid5'.
See commits
0299a7af1e and
4141409eb0
for segtype flag support.
When old snapshot is merged, lvm2 still can report some data about
merged 'snapshot' - i.e. it occupied space in VG.
This patch fixes regression from commit:
6fd20be629
and resolved RHBZ: 1460161
Avoid reporting 'checking result' as maybe - it should
clearly tell 'yes' or 'no'.
Just shuffle printed message to the place, where we
already know the 'maybe' answer.
So instead of printing 'unclear':
checking whether to enable libblkid detection of signatures when wiping... maybe
checking for BLKID... yes
checking whether to use udev-systemd protocol for jobs in background... maybe
checking for SYSTEMD... yes
show this:
checking for BLKID... yes
checking whether to enable libblkid detection of signatures when wiping... yes
checking for SYSTEMD... yes
checking whether to use udev-systemd protocol for jobs in background... yes
Code path missed validation of lvcreate --cachepool argument.
If the non cache-pool LV was passed in, code has still continued
further work and failed later on internal error. Validate this
condition at right place now.
When a combination of thin-pool chunk size and thin-pool data size
goes beyond addressable limit, such volume creation is directly
prohibited.
Maximum usable thin-pool size is calculated with use of maximal support
metadata size (even when it's created smaller) and given chunk-size.
If the value data size is found to be too big, the command reports
error and operation fails.
Previously thin-pool was created however lots of thin-pool data LV was
not usable and this space in VG has been wasted.
Only support RAID conversions on active LVs.
If we'd accept e.g. upconverting linear -> raid1 on inactive
linear LVs, any LV flags passed to the kernel aren't properly
cleared thus errouneously passing them on every activation.
Add respective check to lv_raid_change_image_count() and
move existing one in lv_raid_convert() for better messages.
If during the process of fetching current lvm state we experience an
exception we fail to call set_result on the queued_requests we were
processing. When this happens those threads block forever which causes
the service to stall infinitely. Only clear the queued_requests after
we have called set_result.
We were not adding background tasks to flight recorder. Add the meta
data to the flight recorder when we start the command and update the meta
data when the command is finished. Locking was added to meta data to
prevent concurrent update and returning string representation as these can
happen in two different threads.
vgreduce previously allowed --all and --removemissing together even though
it only actual did the remove missing. The lvm dbus daemon was passing
--all anytime there was no entries in pv_object_paths. This change supplies
--all if and only if we are not removing missing and the pv_object_paths
is empty.
Vgreduce has and continues to enforce the invalid combination of supplying a
device list when you specify --all or --removemissing so we do not need
to check for that invalid combination explicitly in the lvm dbus service as
it's already covered.
Ref: https://bugzilla.redhat.com/show_bug.cgi?id=1455471
Warn about a PV that has the in-use flag set, but appears in
the orphan VG (no VG was found referencing it.)
There are a number of conditions that could lead to this:
. The PV was created with no mdas and is used in a VG with
other PVs (with metadata) that have not yet appeared on
the system. So, no VG metadata is found by lvm which
references the in-use PV with no mdas.
. vgremove could have failed after clearing mdas but
before clearing the in-use flag. In this case, the
in-use flag needs to be manually cleared on the PV.
. The PV may have damanged/unrecognized VG metadata
that lvm could not read.
. The PV may have no mdas, and the PVs with the metadata
may have damaged/unrecognized metadata.