tests/btrfs/201 - pub/scm/linux/kernel/git/jlayton/xfstests-dev - Git at Google

 #! /bin/bash
 # SPDX-License-Identifier: GPL-2.0
 # Copyright (C) 2019 SUSE Linux Products GmbH. All Rights Reserved.
 #
 # FSQA Test No. 201
 #
 # Test that when we have the no-holes feature enabled and a specific metadata
 # layout, if we punch a hole that starts at file offset 0 and fsync the file,
 # after replaying the log the hole exists.
 #
 . ./common/preamble
 _begin_fstest auto quick punch log

 # Override the default cleanup function.
 _cleanup()
 {
 	_cleanup_flakey
 	cd /
 	rm -f $tmp.*
 }

 . ./common/attr
 . ./common/filter
 . ./common/dmflakey

 _require_scratch
 _require_dm_target flakey
 _require_attrs
 _require_xfs_io_command "fpunch"
 _require_btrfs_fs_feature "no_holes"
 _require_btrfs_mkfs_feature "no-holes"
 _require_odirect

 run_test_leading_hole()
 {
     # We create the filesystem with a node size of 64Kb because we need to
     # create a specific metadata layout in order to trigger the bug we are
     # testing. At the moment the node size can not be smaller then the system's
     # page size, so given that the largest possible page size is 64Kb and by
     # default the node size is set to the system's page size value, we explicitly
     # create a filesystem with a 64Kb node size, so that the test can run
     # reliably independently of the system's page size.
     _scratch_mkfs -O no-holes -n $((64 * 1024)) >>$seqres.full 2>&1
     _require_metadata_journaling $SCRATCH_DEV
     _init_flakey
     _mount_flakey

     # Create our first file, which is used just to fill space in a leaf. Its
     # items ocuppy most of the first leaf. We use a large xattr since it's an
     # easy and fast way to fill a lot of leaf space.
     touch $SCRATCH_MNT/foo
     $SETFATTR_PROG -n 'user.x1' -v $(printf '%0.sX' $(seq 1 63617)) \
         $SCRATCH_MNT/foo

    # Create our second file, which we will use to test if fsync persists a hole
    # punch operation against it. Create several extent items for the file, all with
    # a size of 64Kb. The first extent item of this file is located within the first
    # leaf of the fs tree, as its last item, and all the remaining extent items in
    # another leaf.
    local offset=0
    for ((i = 0; i <= 10; i++)); do
        $XFS_IO_PROG -f -d -c "pwrite -S 0xab -b 64K $offset 64K" \
            $SCRATCH_MNT/bar >/dev/null
        offset=$(($offset + 64 * 1024))
    done

    # Make sure everything done so far is durably persisted. We also want to start
    # a new transaction and bump the filesystem generation. We don't fsync because
    # we want to keep the 'full sync' flag in the inode of file 'bar', so that the
    # fsync after the hole punch operation uses the slow path, which is necessary
    # to trigger the bug we are testing.
    sync

    # Now punch a hole that covers only the first extent item of file bar. That
    # is the only extent item in the first leaf of the first tree, so the hole
    # punch operation will drop it and will not touch the second leaf which
    # contains the remaining extent items. These conditions are necessary to
    # trigger the bug we are testing.
    $XFS_IO_PROG -c "fpunch 0 64K" -c "fsync" $SCRATCH_MNT/bar

    echo "File digest before power failure:"
    md5sum $SCRATCH_MNT/bar | _filter_scratch
    # Simulate a power failure and mount the filesystem to check that replaying the
    # log tree succeeds and our file bar has the expected content.
    _flakey_drop_and_remount
    echo "File digest after power failure and log replay:"
    md5sum $SCRATCH_MNT/bar | _filter_scratch

    _unmount_flakey
    _cleanup_flakey
 }

 run_test_middle_hole()
 {
     local hole_offset=$1
     local hole_len=$2

     # We create the filesystem with a node size of 64Kb because we need to
     # create a specific metadata layout in order to trigger the bug we are
     # testing. At the moment the node size can not be smaller then the system's
     # page size, so given that the largest possible page size is 64Kb and by
     # default the node size is set to the system's page size value, we explicitly
     # create a filesystem with a 64Kb node size, so that the test can run
     # reliably independently of the system's page size.
     _scratch_mkfs -O no-holes -n $((64 * 1024)) >>$seqres.full 2>&1
     _require_metadata_journaling $SCRATCH_DEV
     _init_flakey
     _mount_flakey

     # Create our first file, which is used just to fill space in a leaf. Its
     # items ocuppy most of the first leaf. We use a large xattr since it's an
     # easy and fast way to fill a lot of leaf space.
     touch $SCRATCH_MNT/foo
     $SETFATTR_PROG -n 'user.x1' -v $(printf '%0.sX' $(seq 1 63600)) \
         $SCRATCH_MNT/foo

     # Create our second file, which we will use to test if fsync persists a hole
     # punch operation against it. Create several extent items for the file, all
     # with a size of 64Kb. The goal is to have the items of this file span 5
     # btree leafs.
     offset=0
     for ((i = 0; i <= 2000; i++)); do
         $XFS_IO_PROG -f -d -c "pwrite -S 0xab -b 64K $offset 64K" \
             $SCRATCH_MNT/bar >/dev/null
         offset=$(($offset + 64 * 1024))
     done

     # Make sure everything done so far is durably persisted. We also want to
     # start a new transaction and bump the filesystem generation. We don't fsync
     # because we want to keep the 'full sync' flag in the inode of file 'bar',
     # so that the fsync after the hole punch operation uses the slow path, which
     # is necessary to trigger the bug we are testing.
     sync

     # Now punch a hole that covers the entire 3rd leaf. This results in deleting
     # the entire leaf, without touching the 2nd and 4th leafs. The first leaf is
     # touched because the inode item needs to be updated (bytes used, ctime,
     # mtime, etc). After that we modify the last extent, located at the 5th leaf,
     # and then fsync the file. We want to verify that both the hole and the new
     # data are correctly persisted by the fsync.
     $XFS_IO_PROG -c "fpunch $hole_offset $hole_len" \
                  -c "pwrite -S 0xf1 131072000 64K" \
                  -c "fsync" $SCRATCH_MNT/bar >/dev/null

     echo "File digest before power failure:"
     md5sum $SCRATCH_MNT/bar | _filter_scratch
     # Simulate a power failure and mount the filesystem to check that replaying
     # the log tree succeeds and our file bar has the expected content.
     _flakey_drop_and_remount
     echo "File digest after power failure and log replay:"
     md5sum $SCRATCH_MNT/bar | _filter_scratch

     _unmount_flakey
     _cleanup_flakey
 }

 echo "Testing with hole offset 0 hole length 65536"
 run_test_leading_hole

 # Now test cases where file extent items span many leafs and we punch a large
 # hole in the middle of the file, with the goal of getting an entire leaf
 # deleted during the punch hole operation. We test 3 different ranges because
 # depending on whether SELinux is enabled or not the layout of the items in
 # the leafs varies slightly.

 echo
 echo "Testing with hole offset 786432 hole length 54919168"
 run_test_middle_hole 786432 54919168

 echo
 echo "Testing with hole offset 720896 hole length 54919168"
 run_test_middle_hole 720896 54919168

 echo
 echo "Testing with hole offset 655360 hole length 54919168"
 run_test_middle_hole 655360 54919168

 status=0
 exit
	#! /bin/bash
	# SPDX-License-Identifier: GPL-2.0
	# Copyright (C) 2019 SUSE Linux Products GmbH. All Rights Reserved.
	#
	# FSQA Test No. 201
	#
	# Test that when we have the no-holes feature enabled and a specific metadata
	# layout, if we punch a hole that starts at file offset 0 and fsync the file,
	# after replaying the log the hole exists.
	#
	. ./common/preamble
	_begin_fstest auto quick punch log

	# Override the default cleanup function.
	_cleanup()
	{
	_cleanup_flakey
	cd /
	rm -f $tmp.*
	}

	. ./common/attr
	. ./common/filter
	. ./common/dmflakey

	_require_scratch
	_require_dm_target flakey
	_require_attrs
	_require_xfs_io_command "fpunch"
	_require_btrfs_fs_feature "no_holes"
	_require_btrfs_mkfs_feature "no-holes"
	_require_odirect

	run_test_leading_hole()
	{
	# We create the filesystem with a node size of 64Kb because we need to
	# create a specific metadata layout in order to trigger the bug we are
	# testing. At the moment the node size can not be smaller then the system's
	# page size, so given that the largest possible page size is 64Kb and by
	# default the node size is set to the system's page size value, we explicitly
	# create a filesystem with a 64Kb node size, so that the test can run
	# reliably independently of the system's page size.
	_scratch_mkfs -O no-holes -n $((64 * 1024)) >>$seqres.full 2>&1
	_require_metadata_journaling $SCRATCH_DEV
	_init_flakey
	_mount_flakey

	# Create our first file, which is used just to fill space in a leaf. Its
	# items ocuppy most of the first leaf. We use a large xattr since it's an
	# easy and fast way to fill a lot of leaf space.
	touch $SCRATCH_MNT/foo
	$SETFATTR_PROG -n 'user.x1' -v $(printf '%0.sX' $(seq 1 63617)) \
	$SCRATCH_MNT/foo

	# Create our second file, which we will use to test if fsync persists a hole
	# punch operation against it. Create several extent items for the file, all with
	# a size of 64Kb. The first extent item of this file is located within the first
	# leaf of the fs tree, as its last item, and all the remaining extent items in
	# another leaf.
	local offset=0
	for ((i = 0; i <= 10; i++)); do
	$XFS_IO_PROG -f -d -c "pwrite -S 0xab -b 64K $offset 64K" \
	$SCRATCH_MNT/bar >/dev/null
	offset=$(($offset + 64 * 1024))
	done

	# Make sure everything done so far is durably persisted. We also want to start
	# a new transaction and bump the filesystem generation. We don't fsync because
	# we want to keep the 'full sync' flag in the inode of file 'bar', so that the
	# fsync after the hole punch operation uses the slow path, which is necessary
	# to trigger the bug we are testing.
	sync

	# Now punch a hole that covers only the first extent item of file bar. That
	# is the only extent item in the first leaf of the first tree, so the hole
	# punch operation will drop it and will not touch the second leaf which
	# contains the remaining extent items. These conditions are necessary to
	# trigger the bug we are testing.
	$XFS_IO_PROG -c "fpunch 0 64K" -c "fsync" $SCRATCH_MNT/bar

	echo "File digest before power failure:"
	md5sum $SCRATCH_MNT/bar \| _filter_scratch
	# Simulate a power failure and mount the filesystem to check that replaying the
	# log tree succeeds and our file bar has the expected content.
	_flakey_drop_and_remount
	echo "File digest after power failure and log replay:"
	md5sum $SCRATCH_MNT/bar \| _filter_scratch

	_unmount_flakey
	_cleanup_flakey
	}

	run_test_middle_hole()
	{
	local hole_offset=$1
	local hole_len=$2

	# We create the filesystem with a node size of 64Kb because we need to
	# create a specific metadata layout in order to trigger the bug we are
	# testing. At the moment the node size can not be smaller then the system's
	# page size, so given that the largest possible page size is 64Kb and by
	# default the node size is set to the system's page size value, we explicitly
	# create a filesystem with a 64Kb node size, so that the test can run
	# reliably independently of the system's page size.
	_scratch_mkfs -O no-holes -n $((64 * 1024)) >>$seqres.full 2>&1
	_require_metadata_journaling $SCRATCH_DEV
	_init_flakey
	_mount_flakey

	# Create our first file, which is used just to fill space in a leaf. Its
	# items ocuppy most of the first leaf. We use a large xattr since it's an
	# easy and fast way to fill a lot of leaf space.
	touch $SCRATCH_MNT/foo
	$SETFATTR_PROG -n 'user.x1' -v $(printf '%0.sX' $(seq 1 63600)) \
	$SCRATCH_MNT/foo

	# Create our second file, which we will use to test if fsync persists a hole
	# punch operation against it. Create several extent items for the file, all
	# with a size of 64Kb. The goal is to have the items of this file span 5
	# btree leafs.
	offset=0
	for ((i = 0; i <= 2000; i++)); do
	$XFS_IO_PROG -f -d -c "pwrite -S 0xab -b 64K $offset 64K" \
	$SCRATCH_MNT/bar >/dev/null
	offset=$(($offset + 64 * 1024))
	done

	# Make sure everything done so far is durably persisted. We also want to
	# start a new transaction and bump the filesystem generation. We don't fsync
	# because we want to keep the 'full sync' flag in the inode of file 'bar',
	# so that the fsync after the hole punch operation uses the slow path, which
	# is necessary to trigger the bug we are testing.
	sync

	# Now punch a hole that covers the entire 3rd leaf. This results in deleting
	# the entire leaf, without touching the 2nd and 4th leafs. The first leaf is
	# touched because the inode item needs to be updated (bytes used, ctime,
	# mtime, etc). After that we modify the last extent, located at the 5th leaf,
	# and then fsync the file. We want to verify that both the hole and the new
	# data are correctly persisted by the fsync.
	$XFS_IO_PROG -c "fpunch $hole_offset $hole_len" \
	-c "pwrite -S 0xf1 131072000 64K" \
	-c "fsync" $SCRATCH_MNT/bar >/dev/null

	echo "File digest before power failure:"
	md5sum $SCRATCH_MNT/bar \| _filter_scratch
	# Simulate a power failure and mount the filesystem to check that replaying
	# the log tree succeeds and our file bar has the expected content.
	_flakey_drop_and_remount
	echo "File digest after power failure and log replay:"
	md5sum $SCRATCH_MNT/bar \| _filter_scratch

	_unmount_flakey
	_cleanup_flakey
	}

	echo "Testing with hole offset 0 hole length 65536"
	run_test_leading_hole

	# Now test cases where file extent items span many leafs and we punch a large
	# hole in the middle of the file, with the goal of getting an entire leaf
	# deleted during the punch hole operation. We test 3 different ranges because
	# depending on whether SELinux is enabled or not the layout of the items in
	# the leafs varies slightly.

	echo
	echo "Testing with hole offset 786432 hole length 54919168"
	run_test_middle_hole 786432 54919168

	echo
	echo "Testing with hole offset 720896 hole length 54919168"
	run_test_middle_hole 720896 54919168

	echo
	echo "Testing with hole offset 655360 hole length 54919168"
	run_test_middle_hole 655360 54919168

	status=0
	exit