lvm2/test/shell/pvmove-background.sh

#!/usr/bin/env bash

# Copyright (C) 2014 Red Hat, Inc. All rights reserved.
#
# This copyrighted material is made available to anyone wishing to use,
# modify, copy, or redistribute it subject to the terms and conditions
# of the GNU General Public License v.2.
#
# You should have received a copy of the GNU General Public License
# along with this program; if not, write to the Free Software Foundation,
# Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA

# Check pvmove behavior when it's progress and machine is rebooted

SKIP_WITH_LVMLOCKD=1

. lib/inittest

aux prepare_vg 3

for mode in "--atomic" ""
do
lvcreate -aey -l1 -n $lv1 $vg "$dev1"

lvs -o +devices | tee out
grep "$dev1" out

LVM_TEST_TAG="kill_me_$PREFIX" pvmove $mode -i 1 -b "$dev1" "$dev2"
sleep 5 # arbitrary...
lvs -o +devices | tee out
not grep "pvmove" out
lvs -o +devices | tee out
grep "$dev2" out

lvremove -ff $vg
done
tests: use bash 2017-07-02 22:38:32 +03:00			`#!/usr/bin/env bash`

polldaemon: Re-initialise lvmcache properly on fork (fixes RHBZ 1073670). 2014-03-19 19:23:43 +04:00			`# Copyright (C) 2014 Red Hat, Inc. All rights reserved.`
			`#`
			`# This copyrighted material is made available to anyone wishing to use,`
			`# modify, copy, or redistribute it subject to the terms and conditions`
			`# of the GNU General Public License v.2.`
			`#`
			`# You should have received a copy of the GNU General Public License`
			`# along with this program; if not, write to the Free Software Foundation,`
doc: change fsf address Hmm rpmlint suggest fsf is using a different address these days, so lets keep it up-to-date 2016-01-21 13:49:46 +03:00			`# Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA`
polldaemon: Re-initialise lvmcache properly on fork (fixes RHBZ 1073670). 2014-03-19 19:23:43 +04:00
			`# Check pvmove behavior when it's progress and machine is rebooted`

tests: add SKIP_WITH_LVMLOCKD to all tests that don't already used vgcreate $SHARED 2016-02-23 01:13:42 +03:00			`SKIP_WITH_LVMLOCKD=1`

tests: rename test to inittest We are getting into problem when we use 'test' for commands like should/not/... So avoid overloading test name and change it to inittest. 2014-06-06 19:40:04 +04:00			`. lib/inittest`
polldaemon: Re-initialise lvmcache properly on fork (fixes RHBZ 1073670). 2014-03-19 19:23:43 +04:00
			`aux prepare_vg 3`

pvmove: Enable all-or-nothing (atomic) pvmoves pvmove can be used to move single LVs by name or multiple LVs that lie within the specified PV range (e.g. /dev/sdb1:0-1000). When moving more than one LV, the portions of those LVs that are in the range to be moved are added to a new temporary pvmove LV. The LVs then point to the range in the pvmove LV, rather than the PV range. Example 1: We have two LVs in this example. After they were created, the first LV was grown, yeilding two segments in LV1. So, there are two LVs with a total of three segments. Before pvmove: --------- --------- --------- \| LV1s0 \| \| LV2s0 \| \| LV1s1 \| --------- --------- --------- \| \| \| ------------------------------------- PV \| 000 - 255 \| 256 - 511 \| 512 - 767 \| ------------------------------------- After pvmove inserts the temporary pvmove LV: --------- --------- --------- \| LV1s0 \| \| LV2s0 \| \| LV1s1 \| --------- --------- --------- \| \| \| ------------------------------------- pvmove0 \| seg 0 \| seg 1 \| seg 2 \| ------------------------------------- \| \| \| ------------------------------------- PV \| 000 - 255 \| 256 - 511 \| 512 - 767 \| ------------------------------------- Each of the affected LV segments now point to a range of blocks in the pvmove LV, which purposefully corresponds to the segments moved from the original LVs into the temporary pvmove LV. The current implementation goes on from here to mirror the temporary pvmove LV by segment. Further, as the pvmove LV is activated, only one of its segments is actually mirrored (i.e. "moving") at a time. The rest are either complete or not addressed yet. If the pvmove is aborted, those segments that are completed will remain on the destination and those that are not yet addressed or in the process of moving will stay on the source PV. Thus, it is possible to have a partially completed move - some LVs (or certain segments of LVs) on the source PV and some on the destination. Example 2: What 'example 1' might look if it was half-way through the move. --------- --------- --------- \| LV1s0 \| \| LV2s0 \| \| LV1s1 \| --------- --------- --------- \| \| \| ------------------------------------- pvmove0 \| seg 0 \| seg 1 \| seg 2 \| ------------------------------------- \| \| \| \| ------------------------- source PV \| \| 256 - 511 \| 512 - 767 \| \| ------------------------- \| \|\| ------------------------- dest PV \| 000 - 255 \| 256 - 511 \| ------------------------- This update allows the user to specify that they would like the pvmove mirror created "by LV" rather than "by segment". That is, the pvmove LV becomes an image in an encapsulating mirror along with the allocated copy image. Example 3: A pvmove that is performed "by LV" rather than "by segment". --------- --------- \| LV1s0 \| \| LV2s0 \| --------- --------- \| \| ------------------------- pvmove0 \| * LV-level mirror * \| ------------------------- / \ pvmove_mimage0 / pvmove_mimage1 ------------------------- ------------------------- \| seg 0 \| seg 1 \| \| seg 0 \| seg 1 \| ------------------------- ------------------------- \| \| \| \| ------------------------- ------------------------- \| 000 - 255 \| 256 - 511 \| \| 000 - 255 \| 256 - 511 \| ------------------------- ------------------------- source PV dest PV The thing that differentiates a pvmove done in this way and a simple "up-convert" from linear to mirror is the preservation of the distinct segments. A normal up-convert would simply allocate the necessary space with no regard for segment boundaries. The pvmove operation must preserve the segments because they are the critical boundary between the segments of the LVs being moved. So, when the pvmove copy image is allocated, all corresponding segments must be allocated. The code that merges ajoining segments that are part of the same LV when the metadata is written must also be avoided in this case. This method of mirroring is unique enough to warrant its own definitional macro, MIRROR_BY_SEGMENTED_LV. This joins the two existing macros: MIRROR_BY_SEG (for original pvmove) and MIRROR_BY_LV (for user created mirrors). The advantages of performing pvmove in this way is that all of the LVs affected can be moved together. It is an all-or-nothing approach that leaves all LV segments on the source PV if the move is aborted. Additionally, a mirror log can be used (in the future) to provide tracking of progress; allowing the copy to continue where it left off in the event there is a deactivation. 2014-06-18 07:59:36 +04:00			`for mode in "--atomic" ""`
			`do`
tests: use exclusive activation pvmove in cluster needs exlusive activation or cmirrord running. 2014-03-24 13:33:26 +04:00			`lvcreate -aey -l1 -n $lv1 $vg "$dev1"`
polldaemon: Re-initialise lvmcache properly on fork (fixes RHBZ 1073670). 2014-03-19 19:23:43 +04:00
tests: minor update 2016-04-21 00:21:03 +03:00			`lvs -o +devices \| tee out`
			`grep "$dev1" out`

tests: try harder to kill all dangling procs also simplify and make less prone to an error checks for running bg processes inside a pvmove-resume tests 2015-04-28 16:31:47 +03:00			`LVM_TEST_TAG="kill_me_$PREFIX" pvmove $mode -i 1 -b "$dev1" "$dev2"`
polldaemon: Re-initialise lvmcache properly on fork (fixes RHBZ 1073670). 2014-03-19 19:23:43 +04:00			`sleep 5 # arbitrary...`
tests: minor update 2016-04-21 00:21:03 +03:00			`lvs -o +devices \| tee out`
			`not grep "pvmove" out`
			`lvs -o +devices \| tee out`
			`grep "$dev2" out`
pvmove: Enable all-or-nothing (atomic) pvmoves pvmove can be used to move single LVs by name or multiple LVs that lie within the specified PV range (e.g. /dev/sdb1:0-1000). When moving more than one LV, the portions of those LVs that are in the range to be moved are added to a new temporary pvmove LV. The LVs then point to the range in the pvmove LV, rather than the PV range. Example 1: We have two LVs in this example. After they were created, the first LV was grown, yeilding two segments in LV1. So, there are two LVs with a total of three segments. Before pvmove: --------- --------- --------- \| LV1s0 \| \| LV2s0 \| \| LV1s1 \| --------- --------- --------- \| \| \| ------------------------------------- PV \| 000 - 255 \| 256 - 511 \| 512 - 767 \| ------------------------------------- After pvmove inserts the temporary pvmove LV: --------- --------- --------- \| LV1s0 \| \| LV2s0 \| \| LV1s1 \| --------- --------- --------- \| \| \| ------------------------------------- pvmove0 \| seg 0 \| seg 1 \| seg 2 \| ------------------------------------- \| \| \| ------------------------------------- PV \| 000 - 255 \| 256 - 511 \| 512 - 767 \| ------------------------------------- Each of the affected LV segments now point to a range of blocks in the pvmove LV, which purposefully corresponds to the segments moved from the original LVs into the temporary pvmove LV. The current implementation goes on from here to mirror the temporary pvmove LV by segment. Further, as the pvmove LV is activated, only one of its segments is actually mirrored (i.e. "moving") at a time. The rest are either complete or not addressed yet. If the pvmove is aborted, those segments that are completed will remain on the destination and those that are not yet addressed or in the process of moving will stay on the source PV. Thus, it is possible to have a partially completed move - some LVs (or certain segments of LVs) on the source PV and some on the destination. Example 2: What 'example 1' might look if it was half-way through the move. --------- --------- --------- \| LV1s0 \| \| LV2s0 \| \| LV1s1 \| --------- --------- --------- \| \| \| ------------------------------------- pvmove0 \| seg 0 \| seg 1 \| seg 2 \| ------------------------------------- \| \| \| \| ------------------------- source PV \| \| 256 - 511 \| 512 - 767 \| \| ------------------------- \| \|\| ------------------------- dest PV \| 000 - 255 \| 256 - 511 \| ------------------------- This update allows the user to specify that they would like the pvmove mirror created "by LV" rather than "by segment". That is, the pvmove LV becomes an image in an encapsulating mirror along with the allocated copy image. Example 3: A pvmove that is performed "by LV" rather than "by segment". --------- --------- \| LV1s0 \| \| LV2s0 \| --------- --------- \| \| ------------------------- pvmove0 \| * LV-level mirror * \| ------------------------- / \ pvmove_mimage0 / pvmove_mimage1 ------------------------- ------------------------- \| seg 0 \| seg 1 \| \| seg 0 \| seg 1 \| ------------------------- ------------------------- \| \| \| \| ------------------------- ------------------------- \| 000 - 255 \| 256 - 511 \| \| 000 - 255 \| 256 - 511 \| ------------------------- ------------------------- source PV dest PV The thing that differentiates a pvmove done in this way and a simple "up-convert" from linear to mirror is the preservation of the distinct segments. A normal up-convert would simply allocate the necessary space with no regard for segment boundaries. The pvmove operation must preserve the segments because they are the critical boundary between the segments of the LVs being moved. So, when the pvmove copy image is allocated, all corresponding segments must be allocated. The code that merges ajoining segments that are part of the same LV when the metadata is written must also be avoided in this case. This method of mirroring is unique enough to warrant its own definitional macro, MIRROR_BY_SEGMENTED_LV. This joins the two existing macros: MIRROR_BY_SEG (for original pvmove) and MIRROR_BY_LV (for user created mirrors). The advantages of performing pvmove in this way is that all of the LVs affected can be moved together. It is an all-or-nothing approach that leaves all LV segments on the source PV if the move is aborted. Additionally, a mirror log can be used (in the future) to provide tracking of progress; allowing the copy to continue where it left off in the event there is a deactivation. 2014-06-18 07:59:36 +04:00
			`lvremove -ff $vg`
tests: try harder to kill all dangling procs also simplify and make less prone to an error checks for running bg processes inside a pvmove-resume tests 2015-04-28 16:31:47 +03:00			`done`