# vim: filetype=sh
#
# CDDL HEADER START
#
# The contents of this file are subject to the terms of the
# Common Development and Distribution License (the "License").
# You may not use this file except in compliance with the License.
#
# You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
# or http://www.opensolaris.org/os/licensing.
# See the License for the specific language governing permissions
# and limitations under the License.
#
# When distributing Covered Code, include this CDDL HEADER in each
# file and include the License file at usr/src/OPENSOLARIS.LICENSE.
# If applicable, add the following below this CDDL HEADER, with the
# fields enclosed by brackets "[]" replaced with your own identifying
# information: Portions Copyright [yyyy] [name of copyright owner]
#
# CDDL HEADER END
#
#
# Copyright 2009 Sun Microsystems, Inc. All rights reserved.
# Use is subject to license terms.
. ${STF_SUITE}/include/logapi.kshlib
ZFS=${ZFS:-/sbin/zfs}
ZPOOL=${ZPOOL:-/sbin/zpool}
os_name=`uname -s`
# Determine if a test has the necessary requirements to run
function test_requires
{
integer unsupported=0
unsupported_list=""
until [[ $# -eq 0 ]];do
var_name=$1
cmd=$(eval echo \$${1})
if [[ ! "$cmd" != "" ]] ; then
print $var_name is not set
unsupported_list="$var_name $unsupported_list"
((unsupported=unsupported+1))
fi
shift
done
if [[ unsupported -gt 0 ]] ; then
log_unsupported "$unsupported_list commands are unsupported"
else
log_note "All commands are supported"
fi
}
# Determine whether a dataset is mounted
#
# $1 dataset name
# $2 filesystem type; optional - defaulted to zfs
#
# Return 0 if dataset is mounted; 1 if unmounted; 2 on error
function ismounted
{
typeset fstype=$2
[[ -z $fstype ]] && fstype=zfs
typeset out dir name ret
case $fstype in
zfs)
if [[ "$1" == "/"* ]] ; then
for out in $($ZFS mount | $AWK '{print $2}') ; do
[[ $1 == $out ]] && return 0
done
else
for out in $($ZFS mount | $AWK '{print $1}') ; do
[[ $1 == $out ]] && return 0
done
fi
;;
ufs|nfs)
# a = device, b = "on", c = mount point", d = flags
$MOUNT | $GREP $fstype | while read a b c d
do
[[ "$1" == "$a" || "$1" == "$c" ]] && return 0
done
;;
esac
return 1
}
# Return 0 if a dataset is mounted; 1 otherwise
#
# $1 dataset name
# $2 filesystem type; optional - defaulted to zfs
function mounted
{
ismounted $1 $2
(( $? == 0 )) && return 0
return 1
}
# Return 0 if a dataset is unmounted; 1 otherwise
#
# $1 dataset name
# $2 filesystem type; optional - defaulted to zfs
function unmounted
{
ismounted $1 $2
(( $? == 1 )) && return 0
return 1
}
# split line on ","
#
# $1 - line to split
function splitline
{
$ECHO $1 | $SED "s/,/ /g"
}
function default_setup
{
default_setup_noexit "$@"
log_pass
}
#
# Given a list of disks, setup storage pools and datasets.
#
function default_setup_noexit
{
typeset disklist=$1
typeset container=$2
typeset volume=$3
if is_global_zone; then
if poolexists $TESTPOOL ; then
destroy_pool $TESTPOOL
fi
[[ -d /$TESTPOOL ]] && $RM -rf /$TESTPOOL
log_must $ZPOOL create -f $TESTPOOL $disklist
else
reexport_pool
fi
$RM -rf $TESTDIR || log_unresolved Could not remove $TESTDIR
$MKDIR -p $TESTDIR || log_unresolved Could not create $TESTDIR
log_must $ZFS create $TESTPOOL/$TESTFS
log_must $ZFS set mountpoint=$TESTDIR $TESTPOOL/$TESTFS
if [[ -n $container ]]; then
$RM -rf $TESTDIR1 || \
log_unresolved Could not remove $TESTDIR1
$MKDIR -p $TESTDIR1 || \
log_unresolved Could not create $TESTDIR1
log_must $ZFS create $TESTPOOL/$TESTCTR
log_must $ZFS set canmount=off $TESTPOOL/$TESTCTR
log_must $ZFS create $TESTPOOL/$TESTCTR/$TESTFS1
log_must $ZFS set mountpoint=$TESTDIR1 \
$TESTPOOL/$TESTCTR/$TESTFS1
fi
if [[ -n $volume ]]; then
if is_global_zone ; then
log_must $ZFS create -V $VOLSIZE $TESTPOOL/$TESTVOL
else
log_must $ZFS create $TESTPOOL/$TESTVOL
fi
fi
}
#
# Given a list of disks, setup a storage pool, file system and
# a container.
#
function default_container_setup
{
typeset disklist=$1
default_setup "$disklist" "true"
}
#
# Given a list of disks, setup a storage pool,file system
# and a volume.
#
function default_volume_setup
{
typeset disklist=$1
default_setup "$disklist" "" "true"
}
#
# Given a list of disks, setup a storage pool,file system,
# a container and a volume.
#
function default_container_volume_setup
{
typeset disklist=$1
default_setup "$disklist" "true" "true"
}
#
# Create a snapshot on a filesystem or volume. Defaultly create a snapshot on
# filesystem
#
# $1 Existing filesystem or volume name. Default, $TESTFS
# $2 snapshot name. Default, $TESTSNAP
#
function create_snapshot
{
typeset fs_vol=${1:-$TESTFS}
typeset snap=${2:-$TESTSNAP}
[[ -z $fs_vol ]] && log_fail "Filesystem or volume's name is undefined."
[[ -z $snap ]] && log_fail "Snapshot's name is undefined."
if snapexists $fs_vol@$snap; then
log_fail "$fs_vol@$snap already exists."
fi
datasetexists $fs_vol || \
log_fail "$fs_vol must exist."
log_must $ZFS snapshot $fs_vol@$snap
}
#
# Create a clone from a snapshot, default clone name is $TESTCLONE.
#
# $1 Existing snapshot, $TESTPOOL/$TESTFS@$TESTSNAP is default.
# $2 Clone name, $TESTPOOL/$TESTCLONE is default.
#
function create_clone # snapshot clone
{
typeset snap=${1:-$TESTPOOL/$TESTFS@$TESTSNAP}
typeset clone=${2:-$TESTPOOL/$TESTCLONE}
[[ -z $snap ]] && \
log_fail "Snapshot name is undefined."
[[ -z $clone ]] && \
log_fail "Clone name is undefined."
log_must $ZFS clone $snap $clone
}
function default_mirror_setup
{
default_mirror_setup_noexit $1 $2 $3
log_pass
}
#
# Given a pair of disks, set up a storage pool and dataset for the mirror
# @parameters: $1 the primary side of the mirror
# $2 the secondary side of the mirror
# @uses: ZPOOL ZFS TESTPOOL TESTFS
function default_mirror_setup_noexit
{
readonly func="default_mirror_setup_noexit"
typeset primary=$1
typeset secondary=$2
[[ -z $primary ]] && \
log_fail "$func: No parameters passed"
[[ -z $secondary ]] && \
log_fail "$func: No secondary partition passed"
[[ -d /$TESTPOOL ]] && $RM -rf /$TESTPOOL
log_must $ZPOOL create -f $TESTPOOL mirror $@
log_must $ZFS create $TESTPOOL/$TESTFS
log_must $ZFS set mountpoint=$TESTDIR $TESTPOOL/$TESTFS
}
#
# create a number of mirrors.
# We create a number($1) of 2 way mirrors using the pairs of disks named
# on the command line. These mirrors are *not* mounted
# @parameters: $1 the number of mirrors to create
# $... the devices to use to create the mirrors on
# @uses: ZPOOL ZFS TESTPOOL
function setup_mirrors
{
typeset -i nmirrors=$1
shift
while (( nmirrors > 0 )); do
log_must test -n "$1" -a -n "$2"
[[ -d /$TESTPOOL$nmirrors ]] && $RM -rf /$TESTPOOL$nmirrors
log_must $ZPOOL create -f $TESTPOOL$nmirrors mirror $1 $2
shift 2
(( nmirrors = nmirrors - 1 ))
done
}
#
# create a number of raidz pools.
# We create a number($1) of 2 raidz pools using the pairs of disks named
# on the command line. These pools are *not* mounted
# @parameters: $1 the number of pools to create
# $... the devices to use to create the pools on
# @uses: ZPOOL ZFS TESTPOOL
function setup_raidzs
{
typeset -i nraidzs=$1
shift
while (( nraidzs > 0 )); do
log_must test -n "$1" -a -n "$2"
[[ -d /$TESTPOOL$nraidzs ]] && $RM -rf /$TESTPOOL$nraidzs
log_must $ZPOOL create -f $TESTPOOL$nraidzs raidz $1 $2
shift 2
(( nraidzs = nraidzs - 1 ))
done
}
#
# Destroy the configured testpool mirrors.
# the mirrors are of the form ${TESTPOOL}{number}
# @uses: ZPOOL ZFS TESTPOOL
function destroy_mirrors
{
default_cleanup_noexit
log_pass
}
#
# Given a minimum of two disks, set up a storage pool and dataset for the raid-z
# $1 the list of disks
#
function default_raidz_setup
{
typeset disklist="$*"
set -A disks $disklist
if [[ ${#disks[*]} -lt 2 ]]; then
log_fail "A raid-z requires a minimum of two disks."
fi
[[ -d /$TESTPOOL ]] && $RM -rf /$TESTPOOL
log_must $ZPOOL create -f $TESTPOOL raidz $1 $2 $3
log_must $ZFS create $TESTPOOL/$TESTFS
log_must $ZFS set mountpoint=$TESTDIR $TESTPOOL/$TESTFS
log_pass
}
#
# Common function used to cleanup storage pools and datasets.
#
# Invoked at the start of the test suite to ensure the system
# is in a known state, and also at the end of each set of
# sub-tests to ensure errors from one set of tests doesn't
# impact the execution of the next set.
function default_cleanup
{
default_cleanup_noexit
log_pass
}
function all_pools
{
cmd="$ZPOOL list -H -o name | $GREP 'testpool'"
eval $cmd
}
#
# Returns 0 if the system contains any pools that must not be modified by the
# ZFS tests.
#
function other_pools_exist
{
typeset pool_count=`$ZPOOL list -H | $GREP -v '^testpool' | $WC -l`
[ "$pool_count" -ne 0 ]
}
function default_cleanup_noexit
{
typeset exclude=""
typeset pool=""
#
# Destroying the pool will also destroy any
# filesystems it contains.
#
if is_global_zone; then
# Here, we loop through the pools we're allowed to
# destroy, only destroying them if it's safe to do
# so.
for pool in $(all_pools); do
if safe_to_destroy_pool $pool; then
destroy_pool $pool
fi
done
else
typeset fs=""
for fs in $($ZFS list -H -o name \
| $GREP "^$ZONE_POOL/$ZONE_CTR[01234]/"); do
datasetexists $fs && \
log_must $ZFS destroy -Rf $fs
done
# Need cleanup here to avoid garbage dir left.
for fs in $($ZFS list -H -o name \
); do
[[ $fs == /$ZONE_POOL ]] && continue
[[ -d $fs ]] && log_must $RM -rf $fs/*
done
#
# Reset the $ZONE_POOL/$ZONE_CTR[01234] file systems property to
# the default value
#
for fs in $($ZFS list -H -o name \
); do
if [[ $fs == $ZONE_POOL/$ZONE_CTR[01234] ]]; then
log_must $ZFS set reservation=none $fs
log_must $ZFS set recordsize=128K $fs
log_must $ZFS set mountpoint=/$fs $fs
typeset enc=""
enc=$(get_prop encryption $fs)
if [[ $? -ne 0 ]] || [[ -z "$enc" ]] || \
[[ "$enc" == "off" ]]; then
log_must $ZFS set checksum=on $fs
fi
log_must $ZFS set compression=off $fs
log_must $ZFS set atime=on $fs
log_must $ZFS set devices=off $fs
log_must $ZFS set exec=on $fs
log_must $ZFS set setuid=on $fs
log_must $ZFS set readonly=off $fs
log_must $ZFS set snapdir=hidden $fs
log_must $ZFS set aclmode=groupmask $fs
log_must $ZFS set aclinherit=secure $fs
fi
done
fi
[[ -d $TESTDIR ]] && \
log_must $RM -rf $TESTDIR
}
#
# Common function used to cleanup storage pools, file systems
# and containers.
#
function default_container_cleanup
{
if ! is_global_zone; then
reexport_pool
fi
ismounted $TESTPOOL/$TESTCTR/$TESTFS1
[[ $? -eq 0 ]] && \
log_must $ZFS unmount $TESTPOOL/$TESTCTR/$TESTFS1
datasetexists $TESTPOOL/$TESTCTR/$TESTFS1 && \
log_must $ZFS destroy -R $TESTPOOL/$TESTCTR/$TESTFS1
datasetexists $TESTPOOL/$TESTCTR && \
log_must $ZFS destroy -Rf $TESTPOOL/$TESTCTR
[[ -e $TESTDIR1 ]] && \
log_must $RM -rf $TESTDIR1 > /dev/null 2>&1
default_cleanup
}
#
# Common function used to cleanup snapshot of file system or volume. Default to
# delete the file system's snapshot
#
# $1 snapshot name
#
function destroy_snapshot
{
typeset snap=${1:-$TESTPOOL/$TESTFS@$TESTSNAP}
if ! snapexists $snap; then
log_fail "'$snap' does not existed."
fi
#
# For the sake of the value which come from 'get_prop' is not equal
# to the really mountpoint when the snapshot is unmounted. So, firstly
# check and make sure this snapshot's been mounted in current system.
#
typeset mtpt=""
if ismounted $snap; then
mtpt=$(get_prop mountpoint $snap)
(( $? != 0 )) && \
log_fail "get_prop mountpoint $snap failed."
fi
log_must $ZFS destroy $snap
[[ $mtpt != "" && -d $mtpt ]] && \
log_must $RM -rf $mtpt
}
#
# Common function used to cleanup clone.
#
# $1 clone name
#
function destroy_clone
{
typeset clone=${1:-$TESTPOOL/$TESTCLONE}
if ! datasetexists $clone; then
log_fail "'$clone' does not existed."
fi
# With the same reason in destroy_snapshot
typeset mtpt=""
if ismounted $clone; then
mtpt=$(get_prop mountpoint $clone)
(( $? != 0 )) && \
log_fail "get_prop mountpoint $clone failed."
fi
log_must $ZFS destroy $clone
[[ $mtpt != "" && -d $mtpt ]] && \
log_must $RM -rf $mtpt
}
# Return 0 if a snapshot exists; $? otherwise
#
# $1 - snapshot name
function snapexists
{
$ZFS list -H -t snapshot "$1" > /dev/null 2>&1
return $?
}
#
# Set a property to a certain value on a dataset.
# Sets a property of the dataset to the value as passed in.
# @param:
# $1 dataset who's property is being set
# $2 property to set
# $3 value to set property to
# @return:
# 0 if the property could be set.
# non-zero otherwise.
# @use: ZFS
#
function dataset_setprop
{
typeset fn=dataset_setprop
if (( $# < 3 )); then
log_note "$fn: Insufficient parameters (need 3, had $#)"
return 1
fi
typeset output=
output=$($ZFS set $2=$3 $1 2>&1)
typeset rv=$?
if (( rv != 0 )); then
log_note "Setting property on $1 failed."
log_note "property $2=$3"
log_note "Return Code: $rv"
log_note "Output: $output"
return $rv
fi
return 0
}
#
# Assign suite defined dataset properties.
# This function is used to apply the suite's defined default set of
# properties to a dataset.
# @parameters: $1 dataset to use
# @uses: ZFS COMPRESSION_PROP CHECKSUM_PROP
# @returns:
# 0 if the dataset has been altered.
# 1 if no pool name was passed in.
# 2 if the dataset could not be found.
# 3 if the dataset could not have it's properties set.
#
function dataset_set_defaultproperties
{
typeset dataset="$1"
[[ -z $dataset ]] && return 1
typeset confset=
typeset -i found=0
for confset in $($ZFS list); do
if [[ $dataset = $confset ]]; then
found=1
break
fi
done
[[ $found -eq 0 ]] && return 2
if [[ -n $COMPRESSION_PROP ]]; then
dataset_setprop $dataset compression $COMPRESSION_PROP || \
return 3
log_note "Compression set to '$COMPRESSION_PROP' on $dataset"
fi
if [[ -n $CHECKSUM_PROP && $WRAPPER != *"crypto"* ]]; then
dataset_setprop $dataset checksum $CHECKSUM_PROP || \
return 3
log_note "Checksum set to '$CHECKSUM_PROP' on $dataset"
fi
return 0
}
#
# Check a numeric assertion
# @parameter: $@ the assertion to check
# @output: big loud notice if assertion failed
# @use: log_fail
#
function assert
{
(( $@ )) || log_fail $@
}
function wipe_partition_table #<whole_disk_name> [<whole_disk_name> ...]
{
while [[ -n $* ]]; do
typeset diskname=$1
[ ! -e $diskname ] && log_fail "ERROR: $diskname doesn't exist"
if gpart list ${diskname#/dev/} >/dev/null 2>&1; then
wait_for 5 1 $GPART destroy -F $diskname
else
log_note "No GPT partitions detected on $diskname"
fi
log_must $GPART create -s gpt $diskname
shift
done
}
#
# Given a slice, size and disk, this function
# formats the slice to the specified size.
# Size should be specified with units as per
# the `format` command requirements eg. 100mb 3gb
#
function set_partition #<slice_num> <slice_start> <size_plus_units> <whole_disk_name>
{
typeset -i slicenum=$1
typeset start=$2
typeset size=$3
typeset disk=$4
set -A devmap a b c d e f g h
[[ -z $slicenum || -z $size || -z $disk ]] && \
log_fail "The slice, size or disk name is unspecified."
size=`$ECHO $size| sed s/mb/M/`
size=`$ECHO $size| sed s/m/M/`
size=`$ECHO $size| sed s/gb/G/`
size=`$ECHO $size| sed s/g/G/`
[[ -n $start ]] && start="-b $start"
log_must $GPART add -t efi $start -s $size -i $slicenum $disk
return 0
}
function get_disk_size #<disk>
{
typeset disk=$1
diskinfo $disk | awk '{print $3}'
}
function get_available_disk_size #<disk>
{
typeset disk=$1
raw_size=`get_disk_size $disk`
(( available_size = raw_size * 95 / 100 ))
echo $available_size
}
#
# Get the end cyl of the given slice
# #TODO: fix this to be GPT-compatible if we want to use the SMI WRAPPER. This
# function is not necessary on FreeBSD
#
function get_endslice #<disk> <slice>
{
log_fail "get_endslice has not been updated for GPT partitions"
}
#
# Get the first LBA that is beyond the end of the given partition
function get_partition_end #<disk> <partition_index>
{
typeset disk=$1
typeset partition_index=$2
export partition_index
$GPART show $disk | $AWK \
'/^[ \t]/ && $3 ~ ENVIRON["partition_index"] {print $1 + $2}'
}
#
# Given a size,disk and total number of partitions, this function formats the
# disk partitions from 0 to the total partition number with the same specified
# size.
#
function partition_disk #<part_size> <whole_disk_name> <total_parts>
{
typeset -i i=1
typeset part_size=$1
typeset disk_name=$2
typeset total_parts=$3
typeset cyl
wipe_partition_table $disk_name
while (( i <= $total_parts )); do
set_partition $i "" $part_size $disk_name
(( i = i+1 ))
done
}
function size_of_file # fname
{
typeset fname=$1
sz=`stat -f '%z' $fname`
[[ -z "$sz" ]] && log_fail "stat($fname) failed"
$ECHO $sz
return 0
}
#
# This function continues to write to a filenum number of files into dirnum
# number of directories until either $FILE_WRITE returns an error or the
# maximum number of files per directory have been written.
#
# Usage:
# fill_fs [destdir] [dirnum] [filenum] [bytes] [num_writes] [data]
#
# Return value: 0 on success
# non 0 on error
#
# Where :
# destdir: is the directory where everything is to be created under
# dirnum: the maximum number of subdirectories to use, -1 no limit
# filenum: the maximum number of files per subdirectory
# blocksz: number of bytes per block
# num_writes: number of blocks to write
# data: the data that will be written
#
# E.g.
# file_fs /testdir 20 25 1024 256 0
#
# Note: blocksz * num_writes equals the size of the testfile
#
function fill_fs # destdir dirnum filenum blocksz num_writes data
{
typeset destdir=${1:-$TESTDIR}
typeset -i dirnum=${2:-50}
typeset -i filenum=${3:-50}
typeset -i blocksz=${4:-8192}
typeset -i num_writes=${5:-10240}
typeset -i data=${6:-0}
typeset -i retval=0
typeset -i dn=0 # current dir number
typeset -i fn=0 # current file number
while (( retval == 0 )); do
(( dirnum >= 0 && dn >= dirnum )) && break
typeset curdir=$destdir/$dn
log_must $MKDIR -p $curdir
for (( fn = 0; $fn < $filenum && $retval == 0; fn++ )); do
log_cmd $FILE_WRITE -o create -f $curdir/$TESTFILE.$fn \
-b $blocksz -c $num_writes -d $data
retval=$?
done
(( dn = dn + 1 ))
done
return $retval
}
#
# Simple function to get the specified property. If unable to
# get the property then exits.
#
# Note property is in 'parsable' format (-p)
#
function get_prop # property dataset
{
typeset prop_val
typeset prop=$1
typeset dataset=$2
prop_val=$($ZFS get -pH -o value $prop $dataset 2>/dev/null)
if [[ $? -ne 0 ]]; then
log_note "Unable to get $prop property for dataset $dataset"
return 1
fi
$ECHO $prop_val
return 0
}
#
# Simple function to return the lesser of two values.
#
function min
{
typeset first_arg=$1
typeset second_arg=$2
if (( first_arg < second_arg )); then
$ECHO $first_arg
else
$ECHO $second_arg
fi
return 0
}
#
# Simple function to get the specified property of pool. If unable to
# get the property then exits.
#
function get_pool_prop # property pool
{
typeset prop_val
typeset prop=$1
typeset pool=$2
if poolexists $pool ; then
prop_val=$($ZPOOL get $prop $pool 2>/dev/null | $TAIL -1 | \
$AWK '{print $3}')
if [[ $? -ne 0 ]]; then
log_note "Unable to get $prop property for pool " \
"$pool"
return 1
fi
else
log_note "Pool $pool not exists."
return 1
fi
$ECHO $prop_val
return 0
}
# Return 0 if a pool exists; $? otherwise
#
# $1 - pool name
function poolexists
{
typeset pool=$1
if [[ -z $pool ]]; then
log_note "No pool name given."
return 1
fi
$ZPOOL list -H "$pool" > /dev/null 2>&1
return $?
}
# Return 0 if all the specified datasets exist; $? otherwise
#
# $1-n dataset name
function datasetexists
{
if (( $# == 0 )); then
log_note "No dataset name given."
return 1
fi
while (( $# > 0 )); do
$ZFS list -H -t filesystem,snapshot,volume $1 > /dev/null 2>&1 || \
return $?
shift
done
return 0
}
# return 0 if none of the specified datasets exists, otherwise return 1.
#
# $1-n dataset name
function datasetnonexists
{
if (( $# == 0 )); then
log_note "No dataset name given."
return 1
fi
while (( $# > 0 )); do
$ZFS list -H -t filesystem,snapshot,volume $1 > /dev/null 2>&1 && \
return 1
shift
done
return 0
}
#
# Given a mountpoint, or a dataset name, determine if it is shared.
#
# Returns 0 if shared, 1 otherwise.
#
function is_shared
{
typeset fs=$1
typeset mtpt
if [[ $fs != "/"* ]] ; then
if datasetnonexists "$fs" ; then
return 1
else
mtpt=$(get_prop mountpoint "$fs")
case $mtpt in
none|legacy|-) return 1
;;
*) fs=$mtpt
;;
esac
fi
fi
for mtpt in `$SHARE | $AWK '{print $2}'` ; do
if [[ $mtpt == $fs ]] ; then
return 0
fi
done
typeset stat=$($SVCS -H -o STA nfs/server:default)
if [[ $stat != "ON" ]]; then
log_note "Current nfs/server status: $stat"
fi
return 1
}
#
# Given a mountpoint, determine if it is not shared.
#
# Returns 0 if not shared, 1 otherwise.
#
function not_shared
{
typeset fs=$1
is_shared $fs
if (( $? == 0)); then
return 1
fi
return 0
}
#
# Helper function to unshare a mountpoint.
#
function unshare_fs #fs
{
typeset fs=$1
is_shared $fs
if (( $? == 0 )); then
log_must $ZFS unshare $fs
fi
return 0
}
#
# Check NFS server status and trigger it online.
#
function setup_nfs_server
{
# Cannot share directory in non-global zone.
#
if ! is_global_zone; then
log_note "Cannot trigger NFS server by sharing in LZ."
return
fi
typeset nfs_fmri="svc:/network/nfs/server:default"
if [[ $($SVCS -Ho STA $nfs_fmri) != "ON" ]]; then
#
# Only really sharing operation can enable NFS server
# to online permanently.
#
typeset dummy=$TMPDIR/dummy
if [[ -d $dummy ]]; then
log_must $RM -rf $dummy
fi
log_must $MKDIR $dummy
log_must $SHARE $dummy
#
# Waiting for fmri's status to be the final status.
# Otherwise, in transition, an asterisk (*) is appended for
# instances, unshare will reverse status to 'DIS' again.
#
# Waiting for 1's at least.
#
log_must $SLEEP 1
timeout=10
while [[ timeout -ne 0 && $($SVCS -Ho STA $nfs_fmri) == *'*' ]]
do
log_must $SLEEP 1
(( timeout -= 1 ))
done
log_must $UNSHARE $dummy
log_must $RM -rf $dummy
fi
log_note "Current NFS status: '$($SVCS -Ho STA,FMRI $nfs_fmri)'"
}
#
# To verify whether calling process is in global zone
#
# Return 0 if in global zone, 1 in non-global zone
#
function is_global_zone
{
typeset cur_zone=$($ZONENAME 2>/dev/null)
# Zones are not supported on FreeBSD.
if [[ $os_name == "FreeBSD" ]]; then
return 0
fi
if [[ $cur_zone != "global" ]]; then
return 1
fi
return 0
}
#
# Verify whether test is permit to run from
# global zone, local zone, or both
#
# $1 zone limit, could be "global", "local", or "both"(no limit)
#
# Return 0 if permit, otherwise exit with log_unsupported
#
function verify_runnable # zone limit
{
typeset limit=$1
[[ -z $limit ]] && return 0
if is_global_zone ; then
case $limit in
global|both)
break
;;
local) log_unsupported "Test is unable to run from \
global zone."
break
;;
*) log_note "Warning: unknown limit $limit - use both."
;;
esac
else
case $limit in
local|both)
break
;;
global) log_unsupported "Test is unable to run from \
local zone."
break
;;
*) log_note "Warning: unknown limit $limit - use both."
;;
esac
reexport_pool
fi
return 0
}
# Return 0 if create successfully or the pool exists; $? otherwise
# Note: In local zones, this function should return 0 silently.
#
# $1 - pool name
# $2-n - [keyword] devs_list
function create_pool #pool devs_list
{
typeset pool=${1%%/*}
shift
if [[ -z $pool ]]; then
log_note "Missing pool name."
return 1
fi
if poolexists $pool ; then
destroy_pool $pool
fi
if is_global_zone ; then
[[ -d /$pool ]] && $RM -rf /$pool
log_must $ZPOOL create -f $pool $@
fi
return 0
}
# Return 0 if destroy successfully or the pool exists; $? otherwise
# Note: In local zones, this function should return 0 silently.
#
# $1 - pool name
# Destroy pool with the given parameters.
function destroy_pool #pool
{
typeset pool=${1%%/*}
typeset mtpt
if [[ -z $pool ]]; then
log_note "No pool name given."
return 1
fi
if is_global_zone ; then
if poolexists "$pool" ; then
mtpt=$(get_prop mountpoint "$pool")
log_must $ZPOOL destroy -f $pool
[[ -d $mtpt ]] && \
log_must $RM -rf $mtpt
else
log_note "Pool $pool does not exist, skipping destroy."
return 1
fi
fi
return 0
}
#
# Create file vdevs.
# By default this generates sparse vdevs 10GB in size, for performance.
#
function create_vdevs # vdevs
{
typeset vdsize=10G
[ -n "$VDEV_SIZE" ] && vdsize=$VDEV_SIZE
rm -f $@ || return 1
truncate -s $vdsize $@
}
#
# Firstly, create a pool with 5 datasets. Then, create a single zone and
# export the 5 datasets to it. In addition, we also add a ZFS filesystem
# and a zvol device to the zone.
#
# $1 zone name
# $2 zone root directory prefix
# $3 zone ip
#
function zfs_zones_setup #zone_name zone_root zone_ip
{
typeset zone_name=${1:-$(hostname)-z}
typeset zone_root=${2:-"/zone_root"}
typeset zone_ip=${3:-"10.1.1.10"}
typeset prefix_ctr=$ZONE_CTR
typeset pool_name=$ZONE_POOL
typeset -i cntctr=5
typeset -i i=0
# Create pool and 5 container within it
#
[[ -d /$pool_name ]] && $RM -rf /$pool_name
log_must $ZPOOL create -f $pool_name $DISKS
while (( i < cntctr )); do
log_must $ZFS create $pool_name/$prefix_ctr$i
(( i += 1 ))
done
# create a zvol
log_must $ZFS create -V 1g $pool_name/zone_zvol
#
# If current system support slog, add slog device for pool
#
typeset sdevs="$TMPDIR/sdev1 $TMPDIR/sdev2"
log_must create_vdevs $sdevs
log_must $ZPOOL add $pool_name log mirror $sdevs
# this isn't supported just yet.
# Create a filesystem. In order to add this to
# the zone, it must have it's mountpoint set to 'legacy'
# log_must $ZFS create $pool_name/zfs_filesystem
# log_must $ZFS set mountpoint=legacy $pool_name/zfs_filesystem
[[ -d $zone_root ]] && \
log_must $RM -rf $zone_root/$zone_name
[[ ! -d $zone_root ]] && \
log_must $MKDIR -p -m 0700 $zone_root/$zone_name
# Create zone configure file and configure the zone
#
typeset zone_conf=$TMPDIR/zone_conf.${TESTCASE_ID}
$ECHO "create" > $zone_conf
$ECHO "set zonepath=$zone_root/$zone_name" >> $zone_conf
$ECHO "set autoboot=true" >> $zone_conf
i=0
while (( i < cntctr )); do
$ECHO "add dataset" >> $zone_conf
$ECHO "set name=$pool_name/$prefix_ctr$i" >> \
$zone_conf
$ECHO "end" >> $zone_conf
(( i += 1 ))
done
# add our zvol to the zone
$ECHO "add device" >> $zone_conf
$ECHO "set match=/dev/zvol/$pool_name/zone_zvol" >> $zone_conf
$ECHO "end" >> $zone_conf
# add a corresponding zvol to the zone
$ECHO "add device" >> $zone_conf
$ECHO "set match=/dev/zvol/$pool_name/zone_zvol" >> $zone_conf
$ECHO "end" >> $zone_conf
# once it's supported, we'll add our filesystem to the zone
# $ECHO "add fs" >> $zone_conf
# $ECHO "set type=zfs" >> $zone_conf
# $ECHO "set special=$pool_name/zfs_filesystem" >> $zone_conf
# $ECHO "set dir=/export/zfs_filesystem" >> $zone_conf
# $ECHO "end" >> $zone_conf
$ECHO "verify" >> $zone_conf
$ECHO "commit" >> $zone_conf
log_must $ZONECFG -z $zone_name -f $zone_conf
log_must $RM -f $zone_conf
# Install the zone
$ZONEADM -z $zone_name install
if (( $? == 0 )); then
log_note "SUCCESS: $ZONEADM -z $zone_name install"
else
log_fail "FAIL: $ZONEADM -z $zone_name install"
fi
# Install sysidcfg file
#
typeset sysidcfg=$zone_root/$zone_name/root/etc/sysidcfg
$ECHO "system_locale=C" > $sysidcfg
$ECHO "terminal=dtterm" >> $sysidcfg
$ECHO "network_interface=primary {" >> $sysidcfg
$ECHO "hostname=$zone_name" >> $sysidcfg
$ECHO "}" >> $sysidcfg
$ECHO "name_service=NONE" >> $sysidcfg
$ECHO "root_password=mo791xfZ/SFiw" >> $sysidcfg
$ECHO "security_policy=NONE" >> $sysidcfg
$ECHO "timezone=US/Eastern" >> $sysidcfg
# Boot this zone
log_must $ZONEADM -z $zone_name boot
}
#
# Reexport TESTPOOL & TESTPOOL(1-4)
#
function reexport_pool
{
typeset -i cntctr=5
typeset -i i=0
while (( i < cntctr )); do
if (( i == 0 )); then
TESTPOOL=$ZONE_POOL/$ZONE_CTR$i
if ! ismounted $TESTPOOL; then
log_must $ZFS mount $TESTPOOL
fi
else
eval TESTPOOL$i=$ZONE_POOL/$ZONE_CTR$i
if eval ! ismounted \$TESTPOOL$i; then
log_must eval $ZFS mount \$TESTPOOL$i
fi
fi
(( i += 1 ))
done
}
#
# Wait for something to return true, checked by the caller.
#
function wait_for_checked # timeout dt <method> [args...]
{
typeset timeout=$1
typeset dt=$2
shift; shift
typeset -i start=$(date '+%s')
typeset -i endtime
log_note "Waiting $timeout seconds (checked every $dt seconds) for: $*"
((endtime = start + timeout))
while :; do
$*
[ $? -eq 0 ] && return
curtime=$(date '+%s')
[ $curtime -gt $endtime ] && return 1
sleep $dt
done
return 0
}
#
# Wait for something to return true.
#
function wait_for # timeout dt <method> [args...]
{
typeset timeout=$1
typeset dt=$2
shift; shift
wait_for_checked $timeout $dt $* || \
log_fail "ERROR: Timed out waiting for: $*"
}
#
# Verify a given disk is online or offline
#
# Return 0 is pool/disk matches expected state, 1 otherwise
# stateexpr is a regex like ONLINE or REMOVED|UNAVAIL
#
function check_state # pool disk stateexpr
{
typeset pool=$1
typeset disk=${2#/dev/}
disk=${disk#/dev/}
disk=${disk#/dev/}
typeset stateexpr=$3
$ZPOOL status -v $pool | grep "$disk" \
| egrep -i "$stateexpr" > /dev/null 2>&1
return $?
}
#
# Wait for a given disk to leave a state
#
function wait_for_state_exit
{
typeset pool=$1
typeset disk=$2
typeset state=$3
while check_state "$pool" "$disk" "$state"; do
$SLEEP 1
done
}
#
# Wait for a given disk to enter a state
#
function wait_for_state_enter
{
typeset -i timeout=$1
typeset pool=$2
typeset disk=$3
typeset state=$4
log_note "Waiting up to $timeout seconds for $disk to become $state ..."
for ((; $timeout > 0; timeout=$timeout-1)); do
check_state $pool "$disk" "$state"
[ $? -eq 0 ] && return
$SLEEP 1
done
log_must $ZPOOL status $pool
log_fail "ERROR: Disk $disk not marked as $state in $pool"
}
#
# Get the mountpoint of snapshot
# as its mountpoint
#
function snapshot_mountpoint
{
typeset dataset=${1:-$TESTPOOL/$TESTFS@$TESTSNAP}
if [[ $dataset != *@* ]]; then
log_fail "Error name of snapshot '$dataset'."
fi
typeset fs=${dataset%@*}
typeset snap=${dataset#*@}
if [[ -z $fs || -z $snap ]]; then
log_fail "Error name of snapshot '$dataset'."
fi
$ECHO $(get_prop mountpoint $fs)/$(get_snapdir_name)/$snap
}
function pool_maps_intact # pool
{
typeset pool="$1"
if ! $ZDB -bcv $pool; then
return 1
fi
return 0
}
function filesys_has_zil # filesystem
{
typeset filesys="$1"
if ! $ZDB -ivv $filesys | $GREP "ZIL header"; then
return 1
fi
return 0
}
#
# Given a pool and file system, this function will verify the file system
# using the zdb internal tool. Note that the pool is exported and imported
# to ensure it has consistent state.
#
function verify_filesys # pool filesystem dir
{
typeset pool="$1"
typeset filesys="$2"
typeset zdbout="$TMPDIR/zdbout.${TESTCASE_ID}"
shift
shift
typeset dirs=$@
typeset search_path=""
log_note "Calling $ZDB to verify filesystem '$filesys'"
log_must $ZPOOL export $pool
if [[ -n $dirs ]] ; then
for dir in $dirs ; do
search_path="$search_path -d $dir"
done
fi
log_must $ZPOOL import $search_path $pool
$ZDB -cudi $filesys > $zdbout 2>&1
if [[ $? != 0 ]]; then
log_note "Output: $ZDB -cudi $filesys"
$CAT $zdbout
log_fail "$ZDB detected errors with: '$filesys'"
fi
log_must $RM -rf $zdbout
}
#
# Given a pool, and this function list all disks in the pool
#
function get_disklist # pool
{
typeset disklist=""
disklist=$($ZPOOL iostat -v $1 | $NAWK '(NR >4 ) {print $1}' | \
$GREP -v "\-\-\-\-\-" | \
$EGREP -v -e "^(mirror|raidz1|raidz2|spare|log|cache)$" )
$ECHO $disklist
}
#
# Destroy all existing metadevices and state database
#
function destroy_metas
{
typeset metad
for metad in $($METASTAT -p | $AWK '{print $1}'); do
log_must $METACLEAR -rf $metad
done
for metad in $($METADB | $CUT -f6 | $GREP dev | $UNIQ); do
log_must $METADB -fd $metad
done
}
# /**
# This function kills a given list of processes after a time period. We use
# this in the stress tests instead of STF_TIMEOUT so that we can have processes
# run for a fixed amount of time, yet still pass. Tests that hit STF_TIMEOUT
# would be listed as FAIL, which we don't want : we're happy with stress tests
# running for a certain amount of time, then finishing.
#
# @param $1 the time in seconds after which we should terminate these processes
# @param $2..$n the processes we wish to terminate.
# */
function stress_timeout
{
typeset -i TIMEOUT=$1
shift
typeset cpids="$@"
log_note "Waiting for child processes($cpids). " \
"It could last dozens of minutes, please be patient ..."
log_must $SLEEP $TIMEOUT
log_note "Killing child processes after ${TIMEOUT} stress timeout."
typeset pid
for pid in $cpids; do
$PS -p $pid > /dev/null 2>&1
if (( $? == 0 )); then
log_must $KILL -USR1 $pid
fi
done
}
#
# Check whether current OS support a specified feature or not
#
# return 0 if current OS version is in unsupported list, 1 otherwise
#
# $1 unsupported target OS versions
#
function check_version # <OS version>
{
typeset unsupported_vers="$@"
typeset ver
typeset cur_ver=`$UNAME -r`
for ver in $unsupported_vers; do
[[ "$cur_ver" == "$ver" ]] && return 0
done
return 1
}
#
# Verify a given hotspare disk is inuse or avail
#
# Return 0 is pool/disk matches expected state, 1 otherwise
#
function check_hotspare_state # pool disk state{inuse,avail}
{
typeset pool=$1
typeset disk=${2#/dev/}
disk=${disk#/dev/}
disk=${disk#/dev/}
typeset state=$3
cur_state=$(get_device_state $pool $disk "spares")
if [[ $state != ${cur_state} ]]; then
return 1
fi
return 0
}
#
# Verify a given slog disk is inuse or avail
#
# Return 0 is pool/disk matches expected state, 1 otherwise
#
function check_slog_state # pool disk state{online,offline,unavail}
{
typeset pool=$1
typeset disk=${2#/dev/}
disk=${disk#/dev/}
disk=${disk#/dev/}
typeset state=$3
cur_state=$(get_device_state $pool $disk "logs")
if [[ $state != ${cur_state} ]]; then
return 1
fi
return 0
}
#
# Verify a given vdev disk is inuse or avail
#
# Return 0 is pool/disk matches expected state, 1 otherwise
#
function check_vdev_state # pool disk state{online,offline,unavail}
{
typeset pool=$1
typeset disk=${2#/dev/}
disk=${disk#/dev/}
disk=${disk#/dev/}
typeset state=$3
if [[ $WRAPPER == *"smi"* ]]; then
$ECHO $disk | $EGREP "^c[0-F]+([td][0-F]+)+$" > /dev/null 2>&1
if (( $? == 0 )); then
disk=${disk}s2
fi
fi
cur_state=$(get_device_state $pool $disk)
if [[ $state != ${cur_state} ]]; then
return 1
fi
return 0
}
#
# Check the output of 'zpool status -v <pool>',
# and to see if the content of <token> contain the <keyword> specified.
#
# Return 0 is contain, 1 otherwise
#
function check_pool_status # pool token keyword
{
typeset pool=$1
typeset token=$2
typeset keyword=$3
$ZPOOL status -v "$pool" 2>/dev/null | \
$NAWK -v token="$token:" '($1==token) {print $0}' | \
$GREP -i "$keyword" >/dev/null 2>&1
return $?
}
function vdev_pool_error_count
{
typeset errs=$1
if [ -z "$2" ]; then
test $errs -gt 0; ret=$?
else
test $errs -eq $2; ret=$?
fi
log_debug "vdev_pool_error_count: errs='$errs' \$2='$2' ret='$ret'"
return $ret
}
#
# Generate a pool status error file suitable for pool_errors_from_file.
# If the pool is healthy, returns 0. Otherwise, the caller must handle the
# returned temporarily file appropriately.
#
function pool_error_file # <pool>
{
typeset pool="$1"
typeset tmpfile=$TMPDIR/pool_status.${TESTCASE_ID}
$ZPOOL status -x $pool > ${tmpfile}
echo $tmpfile
}
#
# Evaluates <file> counting the number of errors. If vdev specified, only
# that vdev's errors are counted. Returns the total number. <file> will be
# deleted on exit.
#
function pool_errors_from_file # <file> [vdev]
{
typeset file=$1
shift
typeset checkvdev="$2"
typeset line
typeset -i fetchbegin=1
typeset -i errnum=0
typeset -i c_read=0
typeset -i c_write=0
typeset -i c_cksum=0
cat ${file} | $EGREP -v "pool:" | while read line; do
if (( $fetchbegin != 0 )); then
$ECHO $line | $GREP "NAME" >/dev/null 2>&1
(( $? == 0 )) && (( fetchbegin = 0 ))
continue
fi
if [[ -n $checkvdev ]]; then
$ECHO $line | $GREP $checkvdev >/dev/null 2>&1
(( $? != 0 )) && continue
c_read=`$ECHO $line | $AWK '{print $3}'`
c_write=`$ECHO $line | $AWK '{print $4}'`
c_cksum=`$ECHO $line | $AWK '{print $5}'`
if [ $c_read != 0 ] || [ $c_write != 0 ] || \
[ $c_cksum != 0 ]
then
(( errnum = errnum + 1 ))
fi
break
fi
c_read=`$ECHO $line | $AWK '{print $3}'`
c_write=`$ECHO $line | $AWK '{print $4}'`
c_cksum=`$ECHO $line | $AWK '{print $5}'`
if [ $c_read != 0 ] || [ $c_write != 0 ] || \
[ $c_cksum != 0 ]
then
(( errnum = errnum + 1 ))
fi
done
rm -f $file
echo $errnum
}
#
# Returns whether the vdev has the given number of errors.
# If the number is unspecified, any non-zero number returns true.
#
function vdev_has_errors # pool vdev [errors]
{
typeset pool=$1
typeset vdev=$2
typeset tmpfile=$(pool_error_file $pool)
log_note "Original pool status:"
cat $tmpfile
typeset -i errs=$(pool_errors_from_file $tmpfile $vdev)
vdev_pool_error_count $errs $3
}
#
# Returns whether the pool has the given number of errors.
# If the number is unspecified, any non-zero number returns true.
#
function pool_has_errors # pool [errors]
{
typeset pool=$1
typeset tmpfile=$(pool_error_file $pool)
log_note "Original pool status:"
cat $tmpfile
typeset -i errs=$(pool_errors_from_file $tmpfile)
vdev_pool_error_count $errs $2
}
#
# Returns whether clearing $pool at $vdev (if given) succeeds.
#
function pool_clear_succeeds
{
typeset pool="$1"
typeset vdev=$2
$ZPOOL clear $pool $vdev
! pool_has_errors $pool
}
#
# Return whether the pool is healthy
#
function is_pool_healthy # pool
{
typeset pool=$1
typeset healthy_output="pool '$pool' is healthy"
typeset real_output=$($ZPOOL status -x $pool)
if [[ "$real_output" == "$healthy_output" ]]; then
return 0
else
typeset -i ret
$ZPOOL status -x $pool | $GREP "state:" | \
$GREP "FAULTED" >/dev/null 2>&1
ret=$?
(( $ret == 0 )) && return 1
typeset l_scan
typeset errnum
l_scan=$($ZPOOL status -x $pool | $GREP "scan:")
l_scan=${l_scan##*"with"}
errnum=$($ECHO $l_scan | $AWK '{print $1}')
if [ "$errnum" != "0" ]; then
return 1
else
return 0
fi
fi
}
#
# These 5 following functions are instance of check_pool_status()
# is_pool_resilvering - to check if the pool is resilver in progress
# is_pool_resilvered - to check if the pool is resilver completed
# is_pool_scrubbing - to check if the pool is scrub in progress
# is_pool_scrubbed - to check if the pool is scrub completed
# is_pool_scrub_stopped - to check if the pool is scrub stopped
#
function is_pool_resilvering #pool
{
check_pool_status "$1" "scan" "resilver in progress"
return $?
}
function is_pool_resilvered #pool
{
check_pool_status "$1" "scan" "resilvered"
return $?
}
function resilver_happened # pool
{
typeset pool=$1
is_pool_resilvering "$pool" || is_pool_resilvered "$pool"
}
function is_pool_scrubbing #pool
{
check_pool_status "$1" "scan" "scrub in progress"
return $?
}
function is_pool_scrubbed #pool
{
check_pool_status "$1" "scan" "scrub repaired"
return $?
}
function is_pool_scrub_stopped #pool
{
check_pool_status "$1" "scan" "scrub canceled"
return $?
}
function is_pool_state # pool state
{
check_pool_status "$1" "state" "$2"
return $?
}
#
# Erase the partition tables and destroy any zfs labels
#
function cleanup_devices #vdevs
{
for device in $@; do
# Labelclear must happen first, otherwise it may interfere
# with the teardown/setup of GPT labels.
$ZPOOL labelclear -f $device
# Only wipe partition tables for arguments that are disks,
# as opposed to slices (which are valid arguments here).
if geom disk list | grep -qx "Geom name: ${device#/dev/}"; then
wipe_partition_table $device
fi
done
return 0
}
#
# Verify the rsh connectivity to each remote host in RHOSTS.
#
# Return 0 if remote host is accessible; otherwise 1.
# $1 remote host name
# $2 username
#
function verify_rsh_connect #rhost, username
{
typeset rhost=$1
typeset username=$2
typeset rsh_cmd="$RSH -n"
typeset cur_user=
$GETENT hosts $rhost >/dev/null 2>&1
if (( $? != 0 )); then
log_note "$rhost cannot be found from" \
"administrative database."
return 1
fi
$PING $rhost 3 >/dev/null 2>&1
if (( $? != 0 )); then
log_note "$rhost is not reachable."
return 1
fi
if (( ${#username} != 0 )); then
rsh_cmd="$rsh_cmd -l $username"
cur_user="given user \"$username\""
else
cur_user="current user \"`$LOGNAME`\""
fi
if ! $rsh_cmd $rhost $TRUE; then
log_note "$RSH to $rhost is not accessible" \
"with $cur_user."
return 1
fi
return 0
}
#
# Verify the remote host connection via rsh after rebooting
# $1 remote host
#
function verify_remote
{
rhost=$1
#
# The following loop waits for the remote system rebooting.
# Each iteration will wait for 150 seconds. there are
# total 5 iterations, so the total timeout value will
# be 12.5 minutes for the system rebooting. This number
# is an approxiate number.
#
typeset -i count=0
while ! verify_rsh_connect $rhost; do
sleep 150
(( count = count + 1 ))
if (( count > 5 )); then
return 1
fi
done
return 0
}
#
# Replacement function for /usr/bin/rsh. This function will include
# the /usr/bin/rsh and meanwhile return the execution status of the
# last command.
#
# $1 usrname passing down to -l option of /usr/bin/rsh
# $2 remote machine hostname
# $3... command string
#
function rsh_status
{
typeset ruser=$1
typeset rhost=$2
typeset -i ret=0
typeset cmd_str=""
typeset rsh_str=""
shift; shift
cmd_str="$@"
err_file=$TMPDIR/${rhost}.${TESTCASE_ID}.err
if (( ${#ruser} == 0 )); then
rsh_str="$RSH -n"
else
rsh_str="$RSH -n -l $ruser"
fi
$rsh_str $rhost /usr/local/bin/ksh93 -c "'$cmd_str; \
print -u 2 \"status=\$?\"'" \
>/dev/null 2>$err_file
ret=$?
if (( $ret != 0 )); then
$CAT $err_file
$RM -f $std_file $err_file
log_fail "$RSH itself failed with exit code $ret..."
fi
ret=$($GREP -v 'print -u 2' $err_file | $GREP 'status=' | \
$CUT -d= -f2)
(( $ret != 0 )) && $CAT $err_file >&2
$RM -f $err_file >/dev/null 2>&1
return $ret
}
#
# Get the SUNWstc-fs-zfs package installation path in a remote host
# $1 remote host name
#
function get_remote_pkgpath
{
typeset rhost=$1
typeset pkgpath=""
pkgpath=$($RSH -n $rhost "$PKGINFO -l SUNWstc-fs-zfs | $GREP BASEDIR: |\
$CUT -d: -f2")
$ECHO $pkgpath
}
#/**
# A function to find and locate free disks on a system or from given
# disks as the parameter. Since the conversion to ATF, this function is
# superfluous; it is assumed that the user will supply an accurate list of
# disks to use. So we just return the arguments.
#
# $@ given disks to find which are free
#
# @return a string containing the list of available disks
#*/
function find_disks
{
(( first=0 ))
for disk in $@; do
[[ $first == 1 ]] && echo -n " "
(( first=1 ))
case $disk in
/dev/*) echo -n "$disk" ;;
*) echo -n "/dev/$disk" ;;
esac
done
}
# A function to set convenience variables for disks.
function set_disks
{
set -A disk_array $(find_disks $DISKS)
[[ -z "$DISK_ARRAY_LIMIT" ]] && typeset -i DISK_ARRAY_LIMIT=5
export DISK=""
typeset -i i=0
while (( i < ${#disk_array[*]} && i <= $DISK_ARRAY_LIMIT )); do
export DISK${i}="${disk_array[$i]}"
DISKSARRAY="$DISKSARRAY ${disk_array[$i]}"
(( i = i + 1 ))
done
export DISK_ARRAY_NUM=$i
export DISKSARRAY
export disk=$DISK0
}
#
# Add specified user to specified group
#
# $1 group name
# $2 user name
#
function add_user #<group_name> <user_name>
{
typeset gname=$1
typeset uname=$2
if (( ${#gname} == 0 || ${#uname} == 0 )); then
log_fail "group name or user name are not defined."
fi
# Check to see if the user exists.
$ID $uname > /dev/null 2>&1 && return 0
# Assign 1000 as the base uid
typeset -i uid=1000
while true; do
typeset -i ret
$USERADD -u $uid -g $gname -d /var/tmp/$uname -m $uname
ret=$?
case $ret in
0) return 0 ;;
# The uid is not unique
65) ((uid += 1)) ;;
*) return 1 ;;
esac
if [[ $uid == 65000 ]]; then
log_fail "No user id available under 65000 for $uname"
fi
done
return 0
}
#
# Delete the specified user.
#
# $1 login name
#
function del_user #<logname>
{
typeset user=$1
if (( ${#user} == 0 )); then
log_fail "login name is necessary."
fi
if $ID $user > /dev/null 2>&1; then
log_must $USERDEL $user
fi
return 0
}
#
# Select valid gid and create specified group.
#
# $1 group name
#
function add_group #<group_name>
{
typeset group=$1
if (( ${#group} == 0 )); then
log_fail "group name is necessary."
fi
# See if the group already exists.
$GROUPSHOW $group >/dev/null 2>&1
[[ $? == 0 ]] && return 0
# Assign 100 as the base gid
typeset -i gid=100
while true; do
$GROUPADD -g $gid $group > /dev/null 2>&1
typeset -i ret=$?
case $ret in
0) return 0 ;;
# The gid is not unique
65) ((gid += 1)) ;;
*) return 1 ;;
esac
if [[ $gid == 65000 ]]; then
log_fail "No user id available under 65000 for $group"
fi
done
}
#
# Delete the specified group.
#
# $1 group name
#
function del_group #<group_name>
{
typeset grp=$1
if (( ${#grp} == 0 )); then
log_fail "group name is necessary."
fi
$GROUPDEL -n $grp > /dev/null 2>&1
typeset -i ret=$?
case $ret in
# Group does not exist, or was deleted successfully.
0|6|65) return 0 ;;
# Name already exists as a group name
9) log_must $GROUPDEL $grp ;;
*) return 1 ;;
esac
return 0
}
#
# This function will return true if it's safe to destroy the pool passed
# as argument 1. It checks for pools based on zvols and files, and also
# files contained in a pool that may have a different mountpoint.
#
function safe_to_destroy_pool { # $1 the pool name
typeset pool=""
typeset DONT_DESTROY=""
# We check that by deleting the $1 pool, we're not
# going to pull the rug out from other pools. Do this
# by looking at all other pools, ensuring that they
# aren't built from files or zvols contained in this pool.
for pool in $($ZPOOL list -H -o name)
do
ALTMOUNTPOOL=""
# this is a list of the top-level directories in each of the files
# that make up the path to the files the pool is based on
FILEPOOL=$($ZPOOL status -v $pool | $GREP /$1/ | \
$AWK '{print $1}')
# this is a list of the zvols that make up the pool
ZVOLPOOL=$($ZPOOL status -v $pool | $GREP "/dev/zvol/$1$" | \
$AWK '{print $1}')
# also want to determine if it's a file-based pool using an
# alternate mountpoint...
POOL_FILE_DIRS=$($ZPOOL status -v $pool | \
$GREP / | $AWK '{print $1}' | \
$AWK -F/ '{print $2}' | $GREP -v "dev")
for pooldir in $POOL_FILE_DIRS
do
OUTPUT=$($ZFS list -H -r -o mountpoint $1 | \
$GREP "${pooldir}$" | $AWK '{print $1}')
ALTMOUNTPOOL="${ALTMOUNTPOOL}${OUTPUT}"
done
if [ ! -z "$ZVOLPOOL" ]
then
DONT_DESTROY="true"
log_note "Pool $pool is built from $ZVOLPOOL on $1"
fi
if [ ! -z "$FILEPOOL" ]
then
DONT_DESTROY="true"
log_note "Pool $pool is built from $FILEPOOL on $1"
fi
if [ ! -z "$ALTMOUNTPOOL" ]
then
DONT_DESTROY="true"
log_note "Pool $pool is built from $ALTMOUNTPOOL on $1"
fi
done
if [ -z "${DONT_DESTROY}" ]
then
return 0
else
log_note "Warning: it is not safe to destroy $1!"
return 1
fi
}
#
# Get IP address of hostname
# $1 hostname
#
function getipbyhost
{
typeset ip
ip=`$ARP $1 2>/dev/null | $AWK -F\) '{print $1}' \
| $AWK -F\( '{print $2}'`
$ECHO $ip
}
#
# Setup iSCSI initiator to target
# $1 target hostname
#
function iscsi_isetup
{
# check svc:/network/iscsi_initiator:default state, try to enable it
# if the state is not ON
typeset ISCSII_FMRI="svc:/network/iscsi_initiator:default"
if [[ "ON" != $($SVCS -H -o sta $ISCSII_FMRI) ]]; then
log_must $SVCADM enable $ISCSII_FMRI
typeset -i retry=20
while [[ "ON" != $($SVCS -H -o sta $ISCSII_FMRI) && \
( $retry -ne 0 ) ]]
do
(( retry = retry - 1 ))
$SLEEP 1
done
if [[ "ON" != $($SVCS -H -o sta $ISCSII_FMRI) ]]; then
log_fail "$ISCSII_FMRI service can not be enabled!"
fi
fi
log_must $ISCSIADM add discovery-address $(getipbyhost $1)
log_must $ISCSIADM modify discovery --sendtargets enable
log_must $DEVFSADM -i iscsi
}
#
# Check whether iscsi parameter is set as remote
#
# return 0 if iscsi is set as remote, otherwise 1
#
function check_iscsi_remote
{
if [[ $iscsi == "remote" ]] ; then
return 0
else
return 1
fi
}
#
# Check if a volume is a valide iscsi target
# $1 volume name
# return 0 if suceeds, otherwise, return 1
#
function is_iscsi_target
{
typeset dataset=$1
typeset target targets
[[ -z $dataset ]] && return 1
targets=$($ISCSITADM list target | $GREP "Target:" | $AWK '{print $2}')
[[ -z $targets ]] && return 1
for target in $targets; do
[[ $dataset == $target ]] && return 0
done
return 1
}
#
# Get the iSCSI name of a target
# $1 target name
#
function iscsi_name
{
typeset target=$1
typeset name
[[ -z $target ]] && log_fail "No parameter."
if ! is_iscsi_target $target ; then
log_fail "Not a target."
fi
name=$($ISCSITADM list target $target | $GREP "iSCSI Name:" \
| $AWK '{print $2}')
return $name
}
#
# check svc:/system/iscsitgt:default state, try to enable it if the state
# is not ON
#
function iscsitgt_setup
{
log_must $RM -f $ISCSITGTFILE
if [[ "ON" == $($SVCS -H -o sta $ISCSITGT_FMRI) ]]; then
log_note "iscsitgt is already enabled"
return
fi
log_must $SVCADM enable -t $ISCSITGT_FMRI
typeset -i retry=20
while [[ "ON" != $($SVCS -H -o sta $ISCSITGT_FMRI) && \
( $retry -ne 0 ) ]]
do
$SLEEP 1
(( retry = retry - 1 ))
done
if [[ "ON" != $($SVCS -H -o sta $ISCSITGT_FMRI) ]]; then
log_fail "$ISCSITGT_FMRI service can not be enabled!"
fi
log_must $TOUCH $ISCSITGTFILE
}
#
# set DISABLED state of svc:/system/iscsitgt:default
# which is the most suiteable state if $ISCSITGTFILE exists
#
function iscsitgt_cleanup
{
if [[ -e $ISCSITGTFILE ]]; then
log_must $SVCADM disable $ISCSITGT_FMRI
log_must $RM -f $ISCSITGTFILE
fi
}
#
# Close iSCSI initiator to target
# $1 target hostname
#
function iscsi_iclose
{
log_must $ISCSIADM modify discovery --sendtargets disable
log_must $ISCSIADM remove discovery-address $(getipbyhost $1)
$DEVFSADM -Cv
}
#
# Get the available ZFS compression options
# $1 option type zfs_set|zfs_compress
#
function get_compress_opts
{
typeset COMPRESS_OPTS
typeset GZIP_OPTS="gzip gzip-1 gzip-2 gzip-3 gzip-4 gzip-5 \
gzip-6 gzip-7 gzip-8 gzip-9"
if [[ $1 == "zfs_compress" ]] ; then
COMPRESS_OPTS="on lzjb"
elif [[ $1 == "zfs_set" ]] ; then
COMPRESS_OPTS="on off lzjb"
fi
typeset valid_opts="$COMPRESS_OPTS"
$ZFS get 2>&1 | $GREP gzip >/dev/null 2>&1
if [[ $? -eq 0 ]]; then
valid_opts="$valid_opts $GZIP_OPTS"
fi
$ECHO "$valid_opts"
}
#
# Check the subcommand/option is supported
#
function check_opt_support #command, option
{
typeset command=$1
typeset option=$2
if [[ -z $command ]]; then
return 0
elif [[ -z $option ]]; then
eval "$ZFS 2>&1 | $GREP '$command' > /dev/null 2>&1"
else
eval "$ZFS $command 2>&1 | $GREP -- '$option' | \
$GREP -v -- 'User-defined' > /dev/null 2>&1"
fi
return $?
}
#
# Check the zpool subcommand/option is supported
#
function check_zpool_opt_support #command, option
{
typeset command=$1
typeset option=$2
if [[ -z $command ]]; then
return 0
elif [[ -z $option ]]; then
eval "$ZPOOL 2>&1 | $GREP '$command' > /dev/null 2>&1"
else
eval "$ZPOOL $command 2>&1 | $GREP -- '$option' > /dev/null 2>&1"
fi
return $?
}
#
# Verify zfs operation with -p option work as expected
# $1 operation, value could be create, clone or rename
# $2 dataset type, value could be fs or vol
# $3 dataset name
# $4 new dataset name
#
function verify_opt_p_ops
{
typeset ops=$1
typeset datatype=$2
typeset dataset=$3
typeset newdataset=$4
if [[ $datatype != "fs" && $datatype != "vol" ]]; then
log_fail "$datatype is not supported."
fi
# check parameters accordingly
case $ops in
create)
newdataset=$dataset
dataset=""
if [[ $datatype == "vol" ]]; then
ops="create -V $VOLSIZE"
fi
;;
clone)
if [[ -z $newdataset ]]; then
log_fail "newdataset should not be empty" \
"when ops is $ops."
fi
log_must datasetexists $dataset
log_must snapexists $dataset
;;
rename)
if [[ -z $newdataset ]]; then
log_fail "newdataset should not be empty" \
"when ops is $ops."
fi
log_must datasetexists $dataset
log_mustnot snapexists $dataset
;;
*)
log_fail "$ops is not supported."
;;
esac
# make sure the upper level filesystem does not exist
if datasetexists ${newdataset%/*} ; then
log_must $ZFS destroy -rRf ${newdataset%/*}
fi
# without -p option, operation will fail
log_mustnot $ZFS $ops $dataset $newdataset
log_mustnot datasetexists $newdataset ${newdataset%/*}
# with -p option, operation should succeed
log_must $ZFS $ops -p $dataset $newdataset
if ! datasetexists $newdataset ; then
log_fail "-p option does not work for $ops"
fi
# when $ops is create or clone, redo the operation still return zero
if [[ $ops != "rename" ]]; then
log_must $ZFS $ops -p $dataset $newdataset
fi
return 0
}
function get_disk_guid
{
typeset diskname=$1
lastcwd=$(pwd)
cd /dev
guid=$($ZDB -l ${diskname} | ${AWK} '/^ guid:/ {print $2}' | head -1)
cd $lastcwd
echo $guid
}
#
# Get cachefile for a pool.
# Prints the cache file, if there is one.
# Returns 0 for a default zpool.cache, 1 for an explicit one, and 2 for none.
#
function cachefile_for_pool
{
typeset pool=$1
cachefile=$(get_pool_prop cachefile $pool)
[[ $? != 0 ]] && return 1
case "$cachefile" in
none) ret=2 ;;
"-")
ret=2
for dir in /boot/zfs /etc/zfs; do
if [[ -f "${dir}/zpool.cache" ]]; then
cachefile="${dir}/zpool.cache"
ret=0
break
fi
done
;;
*) ret=1;
esac
[[ $ret -eq 0 || $ret -eq 1 ]] && print "$cachefile"
return $ret
}
#
# Assert that the pool is in the appropriate cachefile.
#
function assert_pool_in_cachefile
{
typeset pool=$1
cachefile=$(cachefile_for_pool $pool)
[ $? -ne 0 ] && log_fail "ERROR: Cachefile not created for '$pool'?"
log_must test -e "${cachefile}"
log_must zdb -U ${cachefile} -C ${pool}
}
#
# Get the zdb options given the cachefile state of the pool.
#
function zdb_cachefile_opts
{
typeset pool=$1
typeset vdevdir=$2
typeset opts
if poolexists "$pool"; then
cachefile=$(cachefile_for_pool $pool)
typeset -i ret=$?
case $ret in
0) opts="-C" ;;
1) opts="-U $cachefile -C" ;;
2) opts="-eC" ;;
*) log_fail "Unknown return '$ret'" ;;
esac
else
opts="-eC"
[[ -n "$vdevdir" ]] && opts="$opts -p $vdevdir"
fi
echo "$opts"
}
#
# Get configuration of pool
# $1 pool name
# $2 config name
#
function get_config
{
typeset pool=$1
typeset config=$2
typeset vdevdir=$3
typeset alt_root
typeset zdb_opts
zdb_opts=$(zdb_cachefile_opts $pool $vdevdir)
value=$($ZDB $zdb_opts $pool | $GREP "$config:" | $AWK -F: '{print $2}')
if [[ -n $value ]] ; then
value=${value#'}
value=${value%'}
else
return 1
fi
echo $value
return 0
}
#
# Privated function. Random select one of items from arguments.
#
# $1 count
# $2-n string
#
function _random_get
{
typeset cnt=$1
shift
typeset str="$@"
typeset -i ind
((ind = RANDOM % cnt + 1))
typeset ret=$($ECHO "$str" | $CUT -f $ind -d ' ')
$ECHO $ret
}
#
# Random select one of item from arguments which include NONE string
#
function random_get_with_non
{
typeset -i cnt=$#
((cnt =+ 1))
_random_get "$cnt" "$@"
}
#
# Random select one of item from arguments which doesn't include NONE string
#
function random_get
{
_random_get "$#" "$@"
}
#
# The function will generate a dataset name with specific length
# $1, the length of the name
# $2, the base string to construct the name
#
function gen_dataset_name
{
typeset -i len=$1
typeset basestr="$2"
typeset -i baselen=${#basestr}
typeset -i iter=0
typeset l_name=""
if (( len % baselen == 0 )); then
(( iter = len / baselen ))
else
(( iter = len / baselen + 1 ))
fi
while (( iter > 0 )); do
l_name="${l_name}$basestr"
(( iter -= 1 ))
done
$ECHO $l_name
}
#
# Ensure that a given path has been synced, not just ZIL committed.
#
# XXX On FreeBSD, the sync(8) command (via $SYNC) calls zfs_sync() which just
# does a zil_commit(), as opposed to a txg_wait_synced(). For things that
# require writing to their final destination (e.g. for intentional
# corruption purposes), zil_commit() is not good enough.
#
function force_sync_path # path
{
typeset path="$1"
log_must $ZPOOL export $TESTPOOL
log_must $ZPOOL import -d $path $TESTPOOL
}
#
# Get cksum tuple of dataset
# $1 dataset name
#
# zdb output is like below
# " Dataset pool/fs [ZPL], ID 978, cr_txg 2277, 19.0K, 5 objects,
# rootbp [L0 DMU objset] 400L/200P DVA[0]=<0:1880c00:200>
# DVA[1]=<0:341880c00:200> fletcher4 lzjb LE contiguous birth=2292 fill=5
# cksum=989930ccf:4014fe00c83:da5e388e58b4:1f7332052252ac "
#
function datasetcksum
{
typeset cksum
$SYNC
cksum=$($ZDB -vvv $1 | $GREP "^Dataset $1 \[" | $GREP "cksum" \
| $AWK -F= '{print $6}')
$ECHO $cksum
}
#
# Get cksum of file
# #1 file path
#
function checksum
{
typeset cksum
cksum=$($CKSUM $1 | $AWK '{print $1}')
$ECHO $cksum
}
#
# Get the given disk/slice state from the specific field of the pool
#
function get_device_state #pool disk field("", "spares","logs")
{
typeset pool=$1
typeset disk=${2#/dev/}
disk=${disk#/dev/}
disk=${disk#/dev/}
typeset field=${3:-$pool}
state=$($ZPOOL status -v "$pool" 2>/dev/null | \
$NAWK -v device=$disk -v pool=$pool -v field=$field \
'BEGIN {startconfig=0; startfield=0; }
/config:/ {startconfig=1}
(startconfig==1)&&($1==field) {startfield=1; next;}
(startfield==1)&&($1==device) {print $2; exit;}
(startfield==1)&&(NF>=3)&&($(NF-1)=="was")&&($NF==device) {print $2; exit;}
(startfield==1)&&($1==field || $1 ~ "^spares$" || $1 ~ "^logs$") {startfield=0}')
print $state
}
#
# print the given directory filesystem type
#
# $1 directory name
#
function get_fstype
{
typeset dir=$1
if [[ -z $dir ]]; then
log_fail "Usage: get_fstype <directory>"
fi
$DF -T $dir | $AWK '{print $2}'
}
#
# Given a disk, label it to VTOC regardless what label was on the disk
# $1 disk
#
function labelvtoc
{
typeset disk=$1
if [[ -z $disk ]]; then
log_fail "The disk name is unspecified."
fi
typeset label_file=$TMPDIR/labelvtoc.${TESTCASE_ID}
typeset arch=$($UNAME -p)
if [[ $arch == "i386" ]]; then
$ECHO "label" > $label_file
$ECHO "0" >> $label_file
$ECHO "" >> $label_file
$ECHO "q" >> $label_file
$ECHO "q" >> $label_file
$FDISK -B $disk >/dev/null 2>&1
# wait a while for fdisk finishes
$SLEEP 60
elif [[ $arch == "sparc" ]]; then
$ECHO "label" > $label_file
$ECHO "0" >> $label_file
$ECHO "" >> $label_file
$ECHO "" >> $label_file
$ECHO "" >> $label_file
$ECHO "q" >> $label_file
else
log_fail "unknown arch type"
fi
$FORMAT -e -s -d $disk -f $label_file
typeset -i ret_val=$?
$RM -f $label_file
#
# wait the format to finish
#
$SLEEP 60
if (( ret_val != 0 )); then
log_fail "unable to label $disk as VTOC."
fi
return 0
}
#
# Detect if the given filesystem property is supported in this release
#
# 0 Yes, it is supported
# !0 No, it is not supported
#
function fs_prop_exist
{
typeset prop=$1
if [[ -z $prop ]]; then
log_fail "Usage: fs_prop_exist <property>"
return 1
fi
#
# If the property is shortened column name,
# convert it to the standard name
#
case $prop in
avail) prop=available ;;
refer) prop=referenced ;;
volblock) prop=volblocksize ;;
compress) prop=compression ;;
rdonly) prop=readonly ;;
recsize) prop=recordsize ;;
reserv) prop=reservation ;;
refreserv) prop=refreservation ;;
esac
#
# The zfs get output looks like the following
#
#
# The following properties are supported:
#
# PROPERTY EDIT INHERIT VALUES
#
# available NO NO <size>
# compressratio NO NO <1.00x or higher if compressed>
# creation NO NO <date>
# ... ...
# zoned YES YES on | off
#
# Sizes are specified in bytes with standard units such as K, M, G, etc.
#
#
# Start to extract property from the first blank line after 'PROPERTY'
# and stop at the next blank line
#
$ZFS get 2>&1 | \
$AWK '/PROPERTY/ {start=1; next}
/Sizes/ {start=0}
start==1 {print $1}' | \
$GREP -w "$prop" > /dev/null 2>&1
return $?
}
#
# Detect if the given pool property is supported in this release
#
# 0 Yes, it is supported
# !0 No, it is not supported
#
function pool_prop_exist
{
typeset prop=$1
if [[ -z $prop ]]; then
log_fail "Usage: pool_prop_exist <property>"
return 1
fi
#
# If the property is shortened column name,
# convert it to the standard name
#
case $prop in
avail) prop=available ;;
cap) prop=capacity ;;
replace) prop=autoreplace ;;
esac
#
# The zpool get output looks like the following
#
# usage:
# get <"all" | property[,...]> <pool> ...
#
# the following properties are supported:
#
# PROPERTY EDIT VALUES
#
# available NO <size>
# capacity NO <size>
# guid NO <guid>
# health NO <state>
# size NO <size>
# used NO <size>
# altroot YES <path>
# autoreplace YES on | off
# bootfs YES <filesystem>
# cachefile YES <file> | none
# delegation YES on | off
# failmode YES wait | continue | panic
# version YES <version>
$ZPOOL get 2>&1 | \
$AWK '/PROPERTY/ {start=1; next}
start==1 {print $1}' | \
$GREP -w "$prop" > /dev/null 2>&1
return $?
}
#
# check if the system was installed as zfsroot or not
# return: 0 ture, otherwise false
#
function is_zfsroot
{
$DF -T / | $GREP -q zfs
}
#
# get the root filesystem name if it's zfsroot system.
#
# return: root filesystem name
function get_rootfs
{
typeset rootfs=""
rootfs=$($MOUNT | $AWK '$3 == "\/" && $4~/zfs/ {print $1}')
if [[ -z "$rootfs" ]]; then
log_fail "Can not get rootfs"
fi
$ZFS list $rootfs > /dev/null 2>&1
if (( $? == 0 )); then
$ECHO $rootfs
else
log_fail "This is not a zfsroot system."
fi
}
#
# get the rootfs's pool name
# return:
# rootpool name
#
function get_rootpool
{
typeset rootfs=""
typeset rootpool=""
rootfs=$(get_rootfs)
rootpool=`$ECHO $rootfs | awk -F\/ '{print $1}'`
echo $rootpool
}
#
# Get the sub string from specified source string
#
# $1 source string
# $2 start position. Count from 1
# $3 offset
#
function get_substr #src_str pos offset
{
typeset pos offset
$ECHO $1 | \
$NAWK -v pos=$2 -v offset=$3 '{print substr($0, pos, offset)}'
}
#
# Get the directory path of given device
#
function get_device_dir #device
{
typeset device=$1
$ECHO "/dev"
}
#
# Get the package name
#
function get_package_name
{
typeset dirpath=${1:-$STC_NAME}
print "SUNWstc-${dirpath}" | /usr/bin/sed -e "s/\//-/g"
}
#
# Get the word numbers from a string separated by white space
#
function get_word_count
{
$ECHO $1 | $WC -w
}
#
# To verify if the require numbers of disks is given
#
function verify_disk_count
{
typeset -i min=${2:-1}
typeset -i count=$(get_word_count "$1")
if (( count < min )); then
atf_skip "A minimum of $min disks is required to run." \
" You specified $count disk(s)"
fi
}
#
# Verify that vfs.zfs.vol.recursive is set, so pools can be created using zvols
# as backing stores.
#
function verify_zvol_recursive
{
if [ "`sysctl -n vfs.zfs.vol.recursive`" -ne 1 ]; then
atf_skip "Recursive ZVOLs not enabled"
fi
}
#
# bsdmap disk/slice number to a device path
#
function bsddevmap
{
typeset arg=$1
echo $arg | egrep "*s[0-9]$" > /dev/null 2>&1
if [ $? -eq 0 ]
then
n=`echo $arg| wc -c`
set -A map a b c d e f g h i j
s=`echo $arg | cut -c $((n-1))`
arg=${arg%s[0-9]}${map[$s]}
fi
echo $arg
}
#
# Get the name of the snapshots directory. Traditionally .zfs/snapshots
#
function get_snapdir_name
{
echo ".zfs/snapshot"
}
#
# Unmount all ZFS filesystems except for those that are in the KEEP variable
#
function unmount_all_safe
{
echo $(all_pools) | \
$XARGS -n 1 $ZFS list -H -o name -t all -r | \
$XARGS -n 1 $ZFS unmount
}
#
# Return the highest pool version that this OS can create
#
function get_zpool_version
{
# We assume output from zpool upgrade -v of the form:
#
# This system is currently running ZFS version 2.
# .
# .
typeset ZPOOL_VERSION=$($ZPOOL upgrade -v | $HEAD -1 | \
$AWK '{print $NF}' | $SED -e 's/\.//g')
# Starting with version 5000, the output format changes to:
# This system supports ZFS pool feature flags.
# .
# .
if [[ $ZPOOL_VERSION = "flags" ]]; then
ZPOOL_VERSION=5000
fi
echo $ZPOOL_VERSION
}
# Ensures that zfsd is running, starting it if necessary. Every test that
# interacts with zfsd must call this at startup. This is intended primarily
# to eliminate interference from outside the test suite.
function ensure_zfsd_running
{
if ! service zfsd status > /dev/null 2>&1; then
service zfsd start || service zfsd onestart
service zfsd status > /dev/null 2>&1 ||
log_unsupported "Test requires zfsd"
fi
}
# Temporarily stops ZFSD, because it can interfere with some tests. If this
# function is used, then restart_zfsd _must_ be called in the cleanup routine.
function stop_zfsd
{
$RM -f $TMPDIR/.zfsd_enabled_during_stf_zfs_tests
if [[ -n "$ZFSD" && -x "$ZFSD" ]]; then
if /etc/rc.d/zfsd status > /dev/null; then
log_note "Stopping zfsd"
$TOUCH $TMPDIR/.zfsd_enabled_during_stf_zfs_tests
/etc/rc.d/zfsd stop || /etc/rc.d/zfsd onestop
fi
fi
}
# Restarts zfsd after it has been stopped by stop_zfsd. Intelligently restarts
# only iff zfsd was running at the time stop_zfsd was called.
function restart_zfsd
{
if [[ -f $TMPDIR/.zfsd_enabled_during_stf_zfs_tests ]]; then
log_note "Restarting zfsd"
/etc/rc.d/zfsd start || /etc/rc.d/zfsd onestart
fi
$RM -f $TMPDIR/.zfsd_enabled_during_stf_zfs_tests
}
#
# Using the given <vdev>, obtain the value of the property <propname> for
# the given <tvd> identified by numeric id.
#
function get_tvd_prop # vdev tvd propname
{
typeset vdev=$1
typeset -i tvd=$2
typeset propname=$3
$ZDB -l $vdev | $AWK -v tvd=$tvd -v prop="${propname}:" '
BEGIN { start = 0; }
/^ id:/ && ($2==tvd) { start = 1; next; }
(start==0) { next; }
/^ [a-z]+/ && ($1==prop) { print $2; exit; }
/^ children/ { exit; }
'
}
#
# Convert a DVA into a physical block address. Prints number of blocks.
# This takes the usual printed form, in which offsets are left shifted so
# they represent bytes rather than the native sector count.
#
function dva_to_block_addr # dva
{
typeset dva=$1
typeset offcol=$(echo $dva | cut -f2 -d:)
typeset -i offset="0x${offcol}"
# First add 4MB to skip the boot blocks and first two vdev labels,
# then convert to 512 byte blocks (for use with dd). Note that this
# differs from simply adding 8192 blocks, since the input offset is
# given in bytes and has the actual ashift baked in.
(( offset += 4*1024*1024 ))
(( offset >>= 9 ))
echo "$offset"
}
#
# Convert a RAIDZ DVA into a physical block address. This has the same
# output as dva_to_block_addr (number of blocks from beginning of device), but
# is more complicated due to RAIDZ. ashift is normally always 9, but RAIDZ
# uses the actual tvd ashift instead. Furthermore, the number of vdevs changes
# the actual block for each device.
#
function raidz_dva_to_block_addr # dva ncols ashift
{
typeset dva=$1
typeset -i ncols=$2
typeset -i ashift=$3
typeset -i offset=0x$(echo $dva | cut -f2 -d:)
(( offset >>= ashift ))
typeset -i ioff=$(( (offset + ncols - 1) / ncols ))
# Now add the front 4MB and return.
(( ioff += ( 4194304 >> $ashift ) ))
echo "$ioff"
}
#
# Return the vdevs for the given toplevel vdev number.
# Child vdevs will only be included if they are ONLINE. Output format:
#
# <toplevel vdev type> <nchildren> <child1>[:<child2> ...]
#
# Valid toplevel vdev types are mirror, raidz[1-3], leaf (which can be a
# disk or a file). Note that 'nchildren' can be larger than the number of
# returned children; it represents the number of children regardless of how
# many are actually online.
#
function vdevs_for_tvd # pool tvd
{
typeset pool=$1
typeset -i tvd=$2
$ZPOOL status $pool | $AWK -v want_tvd=$tvd '
BEGIN {
start = 0; tvd = -1; lvd = -1;
type = "UNKNOWN"; disks = ""; disk = "";
nchildren = 0;
}
/NAME.*STATE/ { start = 1; next; }
(start==0) { next; }
(tvd > want_tvd) { exit; }
END { print type " " nchildren " " disks; }
length(disk) > 0 {
if (length(disks) > 0) { disks = disks " "; }
if (substr(disk, 0, 1) == "/") {
disks = disks disk;
} else {
disks = disks "/dev/" disk;
}
disk = "";
}
/^\t(spares|logs)/ { tvd = want_tvd + 1; next; }
/^\t (mirror|raidz[1-3])-[0-9]+/ {
tvd += 1;
(tvd == want_tvd) && type = substr($1, 0, 6);
next;
}
/^\t [\/A-Za-z]+/ {
tvd += 1;
if (tvd == want_tvd) {
(( nchildren += 1 ))
type = "leaf";
($2 == "ONLINE") && disk = $1;
}
next;
}
(tvd < want_tvd) { next; }
/^\t spare-[0-9]+/ { next; }
/^\t [\/A-Za-z]+/ {
(( nchildren += 1 ))
($2 == "ONLINE") && disk = $1;
next;
}
/^\t [\/A-Za-z]+/ {
(( nchildren += 1 ))
($2 == "ONLINE") && disk = $1;
next;
}
'
}
#
# Get a vdev path, ashift & offset for a given pool/dataset and DVA.
# If desired, can also select the toplevel vdev child number.
#
function dva_to_vdev_ashift_off # pool/dataset dva [leaf_vdev_num]
{
typeset poollike=$1
typeset dva=$2
typeset -i leaf_vdev_num=$3
# vdevs are normally 0-indexed while arguments are 1-indexed.
(( leaf_vdev_num += 1 ))
# Strip any child datasets or snapshots.
pool=$(echo $poollike | sed -e 's,[/@].*,,g')
tvd=$(echo $dva | cut -d: -f1)
set -- $(vdevs_for_tvd $pool $tvd)
log_debug "vdevs_for_tvd: $* <EOM>"
tvd_type=$1; shift
nchildren=$1; shift
lvd=$(eval echo \$$leaf_vdev_num)
log_debug "type='$tvd_type' children='$nchildren' lvd='$lvd' dva='$dva'"
case $tvd_type in
raidz*)
ashift=$(get_tvd_prop $lvd $tvd ashift)
log_debug "raidz: ashift='${ashift}'"
off=$(raidz_dva_to_block_addr $dva $nchildren $ashift)
;;
*)
ashift=9
off=$(dva_to_block_addr $dva)
;;
esac
echo "${lvd}:${ashift}:${off}"
}
#
# Get the DVA for the specified dataset's given filepath.
#
function file_dva # dataset filepath [level] [offset] [dva_num]
{
typeset dataset=$1
typeset filepath=$2
typeset -i level=$3
typeset -i offset=$4
typeset -i dva_num=$5
typeset -li blksz=0
typeset -li blknum=0
typeset -li startoff
typeset -li inode
eval `$STAT -s "$filepath"`
inode="$st_ino"
# The inner match is for 'DVA[0]=<0:1b412600:200>', in which the
# text surrounding the actual DVA is a fixed size with 8 characters
# before it and 1 after.
$ZDB -P -vvvvv "$dataset/" $inode | \
$AWK -v level=${level} -v dva_num=${dva_num} '
BEGIN { stage = 0; }
(stage == 0) && ($1=="Object") { stage = 1; next; }
(stage == 1) {
print $3 " " $4;
stage = 2; next;
}
(stage == 2) && /^Indirect blocks/ { stage=3; next; }
(stage < 3) { next; }
match($2, /L[0-9]/) {
if (substr($2, RSTART+1, RLENGTH-1) != level) { next; }
}
match($3, /DVA\[.*>/) {
dva = substr($3, RSTART+8, RLENGTH-9);
if (substr($3, RSTART+4, 1) == dva_num) {
print $1 " " dva;
}
}
' | \
while read line; do
log_debug "params='$blksz/$blknum/$startoff' line='$line'"
if (( blksz == 0 )); then
typeset -i iblksz=$(echo $line | cut -d " " -f1)
typeset -i dblksz=$(echo $line | cut -d " " -f2)
# Calculate the actual desired block starting offset.
if (( level > 0 )); then
typeset -i nbps_per_level
typeset -i indsz
typeset -i i=0
(( nbps_per_level = iblksz / 128 ))
(( blksz = dblksz ))
for (( i = 0; $i < $level; i++ )); do
(( blksz *= nbps_per_level ))
done
else
blksz=$dblksz
fi
(( blknum = offset / blksz ))
(( startoff = blknum * blksz ))
continue
fi
typeset lineoffstr=$(echo $line | cut -d " " -f1)
typeset -i lineoff=$(printf "%d" "0x${lineoffstr}")
typeset dva="$(echo $line | cut -d " " -f2)"
log_debug "str='$lineoffstr' lineoff='$lineoff' dva='$dva'"
if [[ -n "$dva" ]] && (( lineoff == startoff )); then
echo $line | cut -d " " -f2
return 0
fi
done
return 1
}
#
# Corrupt the given dataset's filepath file. This will obtain the first
# level 0 block's DVA and scribble random bits on it.
#
function corrupt_file # dataset filepath [leaf_vdev_num]
{
typeset dataset=$1
typeset filepath=$2
typeset -i leaf_vdev_num="$3"
dva=$(file_dva $dataset $filepath)
[ $? -ne 0 ] && log_fail "ERROR: Can't find file $filepath on $dataset"
vdoff=$(dva_to_vdev_ashift_off $dataset $dva $leaf_vdev_num)
vdev=$(echo $vdoff | cut -d: -f1)
ashift=$(echo $vdoff | cut -d: -f2)
off=$(echo $vdoff | cut -d: -f3)
blocksize=$(( 1 << $ashift ))
log_note "Corrupting ${dataset}'s $filepath on $vdev at DVA $dva with ashift $ashift"
log_must $DD if=/dev/urandom bs=$blocksize of=$vdev seek=$off count=1 conv=notrunc
}
#
# Given a number of files, this function will iterate through
# the loop creating the specified number of files, whose names
# will start with <basename>.
#
# The <data> argument is special: it can be "ITER", in which case
# the -d argument will be the value of the current iteration. It
# can be 0, in which case it will always be 0. Otherwise, it will
# always be the given value.
#
# If <snapbase> is specified, a snapshot will be taken using the
# argument as the snapshot basename.
#
function populate_dir # basename num_files write_count blocksz data snapbase
{
typeset basename=$1
typeset -i num_files=$2
typeset -i write_count=$3
typeset -i blocksz=$4
typeset -i i
typeset data=$5
typeset snapbase="$6"
log_note "populate_dir: data='$data'"
for (( i = 0; i < num_files; i++ )); do
case "$data" in
0) d=0 ;;
ITER) d=$i ;;
*) d=$data ;;
esac
log_must $FILE_WRITE -o create -c $write_count \
-f ${basename}.$i -b $blocksz -d $d
[ -n "$snapbase" ] && log_must $ZFS snapshot ${snapbase}.${i}
done
}
# Reap all children registered in $child_pids.
function reap_children
{
[ -z "$child_pids" ] && return
for wait_pid in $child_pids; do
log_must $KILL $wait_pid
done
child_pids=""
}
# Busy a path. Expects to be reaped via reap_children. Tries to run as
# long and slowly as possible. [num] is taken as a hint; if such a file
# already exists a different one will be chosen.
function busy_path # <path> [num]
{
typeset busypath=$1
typeset -i num=$2
while :; do
busyfile="$busypath/busyfile.${num}"
[ ! -f "$busyfile" ] && break
done
cmd="$DD if=/dev/urandom of=$busyfile bs=512"
( cd $busypath && $cmd ) &
typeset pid=$!
$SLEEP 1
log_must $PS -p $pid
child_pids="$child_pids $pid"
}