tests/qemu-iotests/121 - qemu - Git at Google

 #!/usr/bin/env bash
 # group: rw
 #
 # Test cases for qcow2 refcount table growth
 #
 # Copyright (C) 2015 Red Hat, Inc.
 #
 # This program is free software; you can redistribute it and/or modify
 # it under the terms of the GNU General Public License as published by
 # the Free Software Foundation; either version 2 of the License, or
 # (at your option) any later version.
 #
 # This program is distributed in the hope that it will be useful,
 # but WITHOUT ANY WARRANTY; without even the implied warranty of
 # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 # GNU General Public License for more details.
 #
 # You should have received a copy of the GNU General Public License
 # along with this program.  If not, see <http://www.gnu.org/licenses/>.
 #

 # creator
 owner=hreitz@redhat.com

 seq="$(basename $0)"
 echo "QA output created by $seq"

 status=1	# failure is the default!

 _cleanup()
 {
 	_cleanup_test_img
 }
 trap "_cleanup; exit \$status" 0 1 2 3 15

 # get standard environment, filters and checks
 . ./common.rc
 . ./common.filter

 _supported_fmt qcow2
 _supported_proto file fuse
 _supported_os Linux
 # Refcount structures are used much differently with external data
 # files
 _unsupported_imgopts data_file

 echo
 echo '=== New refcount structures may not conflict with existing structures ==='

 echo
 echo '--- Test 1 ---'
 echo

 # Preallocation speeds up the write operation, but preallocating everything will
 # destroy the purpose of the write; so preallocate one KB less than what would
 # cause a reftable growth...
 _make_test_img -o 'preallocation=metadata,cluster_size=1k' 64512K
 # ...and make the image the desired size afterwards.
 $QEMU_IMG resize "$TEST_IMG" 65M

 # The first write results in a growth of the refcount table during an allocation
 # which has precisely the required size so that the new refcount block allocated
 # in alloc_refcount_block() is right after cluster_index; this did lead to a
 # different refcount block being written to disk (a zeroed cluster) than what is
 # cached (a refblock with one entry having a refcount of 1), and the second
 # write would then result in that cached cluster being marked dirty and then
 # in it being written to disk.
 # This should not happen, the new refcount structures may not conflict with
 # new_block.
 # (Note that for some reason, 'write 63M 1K' does not trigger the problem)
 $QEMU_IO -c 'write 62M 1025K' -c 'write 64M 1M' "$TEST_IMG" | _filter_qemu_io

 _check_test_img


 echo
 echo '--- Test 2 ---'
 echo

 _make_test_img -o 'preallocation=metadata,cluster_size=1k' 64513K
 # This results in an L1 table growth which in turn results in some clusters at
 # the start of the image becoming free
 $QEMU_IMG resize "$TEST_IMG" 65M

 # This write results in a refcount table growth; but the refblock allocated
 # immediately before that (new_block) takes cluster index 4 (which is now free)
 # and is thus not self-describing (in contrast to test 1, where new_block was
 # self-describing). The refcount table growth algorithm then used to place the
 # new refcount structures at cluster index 65536 (which is the same as the
 # cluster_index parameter in this case), allocating a new refcount block for
 # that cluster while new_block already existed, leaking new_block.
 # Therefore, the new refcount structures may not be put at cluster_index
 # (because new_block already describes that cluster, and the new structures try
 # to be self-describing).
 $QEMU_IO -c 'write 63M 130K' "$TEST_IMG" | _filter_qemu_io

 _check_test_img

 echo
 echo '=== Allocating a new refcount block must not leave holes in the image ==='
 echo

 _make_test_img -o 'cluster_size=512,refcount_bits=16' 1M

 # This results in an image with 256 used clusters: the qcow2 header,
 # the refcount table, one refcount block, the L1 table, four L2 tables
 # and 248 data clusters
 $QEMU_IO -c 'write 0 124k' "$TEST_IMG" | _filter_qemu_io

 # 256 clusters of 512 bytes each give us a 128K image
 stat -c "size=%s (expected 131072)" $TEST_IMG

 # All 256 entries of the refcount block are used, so writing a new
 # data cluster also allocates a new refcount block
 $QEMU_IO -c 'write 124k 512' "$TEST_IMG" | _filter_qemu_io

 # Two more clusters, the image size should be 129K now
 stat -c "size=%s (expected 132096)" $TEST_IMG

 # success, all done
 echo
 echo '*** done'
 rm -f $seq.full
 status=0
	#!/usr/bin/env bash
	# group: rw
	#
	# Test cases for qcow2 refcount table growth
	#
	# Copyright (C) 2015 Red Hat, Inc.
	#
	# This program is free software; you can redistribute it and/or modify
	# it under the terms of the GNU General Public License as published by
	# the Free Software Foundation; either version 2 of the License, or
	# (at your option) any later version.
	#
	# This program is distributed in the hope that it will be useful,
	# but WITHOUT ANY WARRANTY; without even the implied warranty of
	# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	# GNU General Public License for more details.
	#
	# You should have received a copy of the GNU General Public License
	# along with this program. If not, see <http://www.gnu.org/licenses/>.
	#

	# creator
	owner=hreitz@redhat.com

	seq="$(basename $0)"
	echo "QA output created by $seq"

	status=1 # failure is the default!

	_cleanup()
	{
	_cleanup_test_img
	}
	trap "_cleanup; exit \$status" 0 1 2 3 15

	# get standard environment, filters and checks
	. ./common.rc
	. ./common.filter

	_supported_fmt qcow2
	_supported_proto file fuse
	_supported_os Linux
	# Refcount structures are used much differently with external data
	# files
	_unsupported_imgopts data_file

	echo
	echo '=== New refcount structures may not conflict with existing structures ==='

	echo
	echo '--- Test 1 ---'
	echo

	# Preallocation speeds up the write operation, but preallocating everything will
	# destroy the purpose of the write; so preallocate one KB less than what would
	# cause a reftable growth...
	_make_test_img -o 'preallocation=metadata,cluster_size=1k' 64512K
	# ...and make the image the desired size afterwards.
	$QEMU_IMG resize "$TEST_IMG" 65M

	# The first write results in a growth of the refcount table during an allocation
	# which has precisely the required size so that the new refcount block allocated
	# in alloc_refcount_block() is right after cluster_index; this did lead to a
	# different refcount block being written to disk (a zeroed cluster) than what is
	# cached (a refblock with one entry having a refcount of 1), and the second
	# write would then result in that cached cluster being marked dirty and then
	# in it being written to disk.
	# This should not happen, the new refcount structures may not conflict with
	# new_block.
	# (Note that for some reason, 'write 63M 1K' does not trigger the problem)
	$QEMU_IO -c 'write 62M 1025K' -c 'write 64M 1M' "$TEST_IMG" \| _filter_qemu_io

	_check_test_img


	echo
	echo '--- Test 2 ---'
	echo

	_make_test_img -o 'preallocation=metadata,cluster_size=1k' 64513K
	# This results in an L1 table growth which in turn results in some clusters at
	# the start of the image becoming free
	$QEMU_IMG resize "$TEST_IMG" 65M

	# This write results in a refcount table growth; but the refblock allocated
	# immediately before that (new_block) takes cluster index 4 (which is now free)
	# and is thus not self-describing (in contrast to test 1, where new_block was
	# self-describing). The refcount table growth algorithm then used to place the
	# new refcount structures at cluster index 65536 (which is the same as the
	# cluster_index parameter in this case), allocating a new refcount block for
	# that cluster while new_block already existed, leaking new_block.
	# Therefore, the new refcount structures may not be put at cluster_index
	# (because new_block already describes that cluster, and the new structures try
	# to be self-describing).
	$QEMU_IO -c 'write 63M 130K' "$TEST_IMG" \| _filter_qemu_io

	_check_test_img

	echo
	echo '=== Allocating a new refcount block must not leave holes in the image ==='
	echo

	_make_test_img -o 'cluster_size=512,refcount_bits=16' 1M

	# This results in an image with 256 used clusters: the qcow2 header,
	# the refcount table, one refcount block, the L1 table, four L2 tables
	# and 248 data clusters
	$QEMU_IO -c 'write 0 124k' "$TEST_IMG" \| _filter_qemu_io

	# 256 clusters of 512 bytes each give us a 128K image
	stat -c "size=%s (expected 131072)" $TEST_IMG

	# All 256 entries of the refcount block are used, so writing a new
	# data cluster also allocates a new refcount block
	$QEMU_IO -c 'write 124k 512' "$TEST_IMG" \| _filter_qemu_io

	# Two more clusters, the image size should be 129K now
	stat -c "size=%s (expected 132096)" $TEST_IMG

	# success, all done
	echo
	echo '*** done'
	rm -f $seq.full
	status=0