freebsd-nq/scripts/zconfig.sh
Brian Behlendorf 0ee8118bd3 Add zfault zpool configurations and tests
Eleven new zpool configurations were added to allow testing of various
failure cases.  The first 5 zpool configurations leverage the 'faulty'
md device type which allow us to simuluate IO errors at the block layer.
The last 6 zpool configurations leverage the scsi_debug module provided
by modern kernels.  This device allows you to create virtual scsi
devices which are backed by a ram disk.  With this setup we can verify
the full IO stack by injecting faults at the lowest layer.  Both methods
of fault injection are important to verifying the IO stack.

The zfs code itself also provides a mechanism for error injection
via the zinject command line tool.  While we should also take advantage
of this appraoch to validate the code it does not address any of the
Linux integration issues which are the most concerning.  For the
moment we're trusting that the upstream Solaris guys are running
zinject and would have caught internal zfs logic errors.

Currently, there are 6 r/w test cases layered on top of the 'faulty'
md devices.  They include 3 writes tests for soft/transient errors,
hard/permenant errors, and all writes error to the device.  There
are 3 matching read tests for soft/transient errors, hard/permenant
errors, and fixable read error with a write.  Although for this last
case zfs doesn't do anything special.

The seventh test case verifies zfs detects and corrects checksum
errors.  In this case one of the drives is extensively damaged and
by dd'ing over large sections of it.  We then ensure zfs logs the
issue and correctly rebuilds the damage.

The next  test cases use the scsi_debug configuration to injects error
at the bottom of the scsi stack.  This ensures we find any flaws in the
scsi midlayer or our usage of it.  Plus it stresses the device specific
retry, timeout, and error handling outside of zfs's control.

The eighth test case is to verify that the system correctly handles an
intermittent device timeout.  Here the scsi_debug device drops 1 in N
requests resulting in a retry either at the block level.  The ZFS code
does specify the FAILFAST option but it turns out that for this case
the Linux IO stack with still retry the command.  The FAILFAST logic
located in scsi_noretry_cmd() does no seem to apply to the simply
timeout case.  It appears to be more targeted to specific device or
transport errors from the lower layers.

The ninth test case handles a persistent failure in which the device
is removed from the system by Linux.  The test verifies that the failure
is detected, the device is made unavailable, and then can be successfully
re-add when brought back online.  Additionally, it ensures that errors
and events are logged to the correct places and the no data corruption
has occured due to the failure.
2010-10-12 15:20:03 -07:00

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#!/bin/bash
#
# ZFS/ZPOOL configuration test script.
basedir="$(dirname $0)"
SCRIPT_COMMON=common.sh
if [ -f "${basedir}/${SCRIPT_COMMON}" ]; then
. "${basedir}/${SCRIPT_COMMON}"
else
echo "Missing helper script ${SCRIPT_COMMON}" && exit 1
fi
PROG=zconfig.sh
usage() {
cat << EOF
USAGE:
$0 [hvc]
DESCRIPTION:
ZFS/ZPOOL configuration tests
OPTIONS:
-h Show this message
-v Verbose
-c Cleanup lo+file devices at start
EOF
}
while getopts 'hvct:s:?' OPTION; do
case $OPTION in
h)
usage
exit 1
;;
v)
VERBOSE=1
;;
c)
CLEANUP=1
;;
t)
TESTS_RUN=($OPTARG)
;;
s)
TESTS_SKIP=($OPTARG)
;;
?)
usage
exit
;;
esac
done
if [ $(id -u) != 0 ]; then
die "Must run as root"
fi
# Perform pre-cleanup is requested
if [ ${CLEANUP} ]; then
cleanup_md_devices
cleanup_loop_devices
rm -f /tmp/zpool.cache.*
fi
zconfig_partition() {
local DEVICE=$1
local START=$2
local END=$3
local TMP_FILE=`mktemp`
/sbin/sfdisk -q ${DEVICE} << EOF &>${TMP_FILE} || fail 4
${START},${END}
;
;
;
EOF
rm ${TMP_FILE}
}
# Validate persistent zpool.cache configuration.
test_1() {
local POOL_NAME=test1
local TMP_FILE1=`mktemp`
local TMP_FILE2=`mktemp`
local TMP_CACHE=`mktemp -p /tmp zpool.cache.XXXXXXXX`
# Create a pool save its status for comparison.
${ZFS_SH} zfs="spa_config_path=${TMP_CACHE}" || fail 1
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 || fail 2
${ZPOOL} status ${POOL_NAME} >${TMP_FILE1} || fail 3
# Unload/load the module stack and verify the pool persists.
${ZFS_SH} -u || fail 4
${ZFS_SH} zfs="spa_config_path=${TMP_CACHE}" || fail 5
${ZPOOL} status ${POOL_NAME} >${TMP_FILE2} || fail 6
cmp ${TMP_FILE1} ${TMP_FILE2} || fail 7
# Cleanup the test pool and temporary files
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 -d || fail 8
rm -f ${TMP_FILE1} ${TMP_FILE2} ${TMP_CACHE} || fail 9
${ZFS_SH} -u || fail 10
pass
}
run_test 1 "persistent zpool.cache"
# Validate ZFS disk scanning and import w/out zpool.cache configuration.
test_2() {
local POOL_NAME=test2
local TMP_FILE1=`mktemp`
local TMP_FILE2=`mktemp`
local TMP_CACHE=`mktemp -p /tmp zpool.cache.XXXXXXXX`
# Create a pool save its status for comparison.
${ZFS_SH} zfs="spa_config_path=${TMP_CACHE}" || fail 1
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 || fail 2
${ZPOOL} status ${POOL_NAME} >${TMP_FILE1} || fail 3
# Unload the module stack, remove the cache file, load the module
# stack and attempt to probe the disks to import the pool. As
# a cross check verify the old pool state against the imported.
${ZFS_SH} -u || fail 4
rm -f ${TMP_CACHE} || fail 5
${ZFS_SH} zfs="spa_config_path=${TMP_CACHE}" || fail 6
${ZPOOL} import | grep ${POOL_NAME} >/dev/null || fail 7
${ZPOOL} import ${POOL_NAME} || fail 8
${ZPOOL} status ${POOL_NAME} >${TMP_FILE2} || fail 9
cmp ${TMP_FILE1} ${TMP_FILE2} || fail 10
# Cleanup the test pool and temporary files
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 -d || fail 11
rm -f ${TMP_FILE1} ${TMP_FILE2} || fail 12
${ZFS_SH} -u || fail 13
pass
}
run_test 2 "scan disks for pools to import"
zconfig_zvol_device_stat() {
local EXPECT=$1
local POOL_NAME=/dev/$2
local ZVOL_NAME=/dev/$3
local SNAP_NAME=/dev/$4
local CLONE_NAME=/dev/$5
local COUNT=0
# Briefly delay for udev
sleep 3
# Pool exists
stat ${POOL_NAME} &>/dev/null && let COUNT=$COUNT+1
# Volume and partitions
stat ${ZVOL_NAME} &>/dev/null && let COUNT=$COUNT+1
stat ${ZVOL_NAME}1 &>/dev/null && let COUNT=$COUNT+1
stat ${ZVOL_NAME}2 &>/dev/null && let COUNT=$COUNT+1
# Snapshot with partitions
stat ${SNAP_NAME} &>/dev/null && let COUNT=$COUNT+1
stat ${SNAP_NAME}1 &>/dev/null && let COUNT=$COUNT+1
stat ${SNAP_NAME}2 &>/dev/null && let COUNT=$COUNT+1
# Clone with partitions
stat ${CLONE_NAME} &>/dev/null && let COUNT=$COUNT+1
stat ${CLONE_NAME}1 &>/dev/null && let COUNT=$COUNT+1
stat ${CLONE_NAME}2 &>/dev/null && let COUNT=$COUNT+1
if [ $EXPECT -ne $COUNT ]; then
return 1
fi
return 0
}
# zpool import/export device check
# (1 volume, 2 partitions, 1 snapshot, 1 clone)
test_3() {
local POOL_NAME=tank
local ZVOL_NAME=volume
local SNAP_NAME=snap
local CLONE_NAME=clone
local FULL_ZVOL_NAME=${POOL_NAME}/${ZVOL_NAME}
local FULL_SNAP_NAME=${POOL_NAME}/${ZVOL_NAME}@${SNAP_NAME}
local FULL_CLONE_NAME=${POOL_NAME}/${CLONE_NAME}
local TMP_CACHE=`mktemp -p /tmp zpool.cache.XXXXXXXX`
# Create a pool, volume, partition, snapshot, and clone.
${ZFS_SH} zfs="spa_config_path=${TMP_CACHE}" || fail 1
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 || fail 2
${ZFS} create -V 100M ${FULL_ZVOL_NAME} || fail 3
zconfig_partition /dev/${FULL_ZVOL_NAME} 0 64 || fail 4
${ZFS} snapshot ${FULL_SNAP_NAME} || fail 5
${ZFS} clone ${FULL_SNAP_NAME} ${FULL_CLONE_NAME} || fail 6
# Verify the devices were created
zconfig_zvol_device_stat 10 ${POOL_NAME} ${FULL_ZVOL_NAME} \
${FULL_SNAP_NAME} ${FULL_CLONE_NAME} || fail 7
# Export the pool
${ZPOOL} export ${POOL_NAME} || fail 8
# verify the devices were removed
zconfig_zvol_device_stat 0 ${POOL_NAME} ${FULL_ZVOL_NAME} \
${FULL_SNAP_NAME} ${FULL_CLONE_NAME} || fail 9
# Import the pool, wait 1 second for udev
${ZPOOL} import ${POOL_NAME} || fail 10
# Verify the devices were created
zconfig_zvol_device_stat 10 ${POOL_NAME} ${FULL_ZVOL_NAME} \
${FULL_SNAP_NAME} ${FULL_CLONE_NAME} || fail 11
# Destroy the pool and consequently the devices
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 -d || fail 12
# verify the devices were removed
zconfig_zvol_device_stat 0 ${POOL_NAME} ${FULL_ZVOL_NAME} \
${FULL_SNAP_NAME} ${FULL_CLONE_NAME} || fail 13
${ZFS_SH} -u || fail 14
rm -f ${TMP_CACHE} || fail 15
pass
}
run_test 3 "zpool import/export device"
# zpool insmod/rmmod device check (1 volume, 1 snapshot, 1 clone)
test_4() {
POOL_NAME=tank
ZVOL_NAME=volume
SNAP_NAME=snap
CLONE_NAME=clone
FULL_ZVOL_NAME=${POOL_NAME}/${ZVOL_NAME}
FULL_SNAP_NAME=${POOL_NAME}/${ZVOL_NAME}@${SNAP_NAME}
FULL_CLONE_NAME=${POOL_NAME}/${CLONE_NAME}
TMP_CACHE=`mktemp -p /tmp zpool.cache.XXXXXXXX`
# Create a pool, volume, snapshot, and clone
${ZFS_SH} zfs="spa_config_path=${TMP_CACHE}" || fail 1
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 || fail 2
${ZFS} create -V 100M ${FULL_ZVOL_NAME} || fail 3
zconfig_partition /dev/${FULL_ZVOL_NAME} 0 64 || fail 4
${ZFS} snapshot ${FULL_SNAP_NAME} || fail 5
${ZFS} clone ${FULL_SNAP_NAME} ${FULL_CLONE_NAME} || fail 6
# Verify the devices were created
zconfig_zvol_device_stat 10 ${POOL_NAME} ${FULL_ZVOL_NAME} \
${FULL_SNAP_NAME} ${FULL_CLONE_NAME} || fail 7
# Unload the modules
${ZFS_SH} -u || fail 8
# Verify the devices were removed
zconfig_zvol_device_stat 0 ${POOL_NAME} ${FULL_ZVOL_NAME} \
${FULL_SNAP_NAME} ${FULL_CLONE_NAME} || fail 9
# Load the modules, wait 1 second for udev
${ZFS_SH} zfs="spa_config_path=${TMP_CACHE}" || fail 10
# Verify the devices were created
zconfig_zvol_device_stat 10 ${POOL_NAME} ${FULL_ZVOL_NAME} \
${FULL_SNAP_NAME} ${FULL_CLONE_NAME} || fail 11
# Destroy the pool and consequently the devices
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 -d || fail 12
# Verify the devices were removed
zconfig_zvol_device_stat 0 ${POOL_NAME} ${FULL_ZVOL_NAME} \
${FULL_SNAP_NAME} ${FULL_CLONE_NAME} || fail 13
${ZFS_SH} -u || fail 14
rm -f ${TMP_CACHE} || fail 15
pass
}
run_test 4 "zpool insmod/rmmod device"
# ZVOL volume sanity check
test_5() {
local POOL_NAME=tank
local ZVOL_NAME=fish
local FULL_NAME=${POOL_NAME}/${ZVOL_NAME}
local SRC_DIR=/bin/
local TMP_CACHE=`mktemp -p /tmp zpool.cache.XXXXXXXX`
# Create a pool and volume.
${ZFS_SH} zfs="spa_config_path=${TMP_CACHE}" || fail 1
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 || fail 2
${ZFS} create -V 400M ${FULL_NAME} || fail 3
# Partition the volume, for a 400M volume there will be
# 812 cylinders, 16 heads, and 63 sectors per track.
zconfig_partition /dev/${FULL_NAME} 0 812
# Format the partition with ext3.
/sbin/mkfs.ext3 -q /dev/${FULL_NAME}1 || fail 5
# Mount the ext3 filesystem and copy some data to it.
mkdir -p /tmp/${ZVOL_NAME}1 || fail 6
mount /dev/${FULL_NAME}1 /tmp/${ZVOL_NAME}1 || fail 7
cp -RL ${SRC_DIR} /tmp/${ZVOL_NAME}1 || fail 8
sync
# Verify the copied files match the original files.
diff -ur ${SRC_DIR} /tmp/${ZVOL_NAME}1${SRC_DIR} &>/dev/null || fail 9
# Remove the files, umount, destroy the volume and pool.
rm -Rf /tmp/${ZVOL_NAME}1${SRC_DIR}* || fail 10
umount /tmp/${ZVOL_NAME}1 || fail 11
rmdir /tmp/${ZVOL_NAME}1 || fail 12
${ZFS} destroy ${FULL_NAME} || fail 13
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 -d || fail 14
${ZFS_SH} -u || fail 15
rm -f ${TMP_CACHE} || fail 16
pass
}
run_test 5 "zvol+ext3 volume"
# ZVOL snapshot sanity check
test_6() {
local POOL_NAME=tank
local ZVOL_NAME=fish
local SNAP_NAME=pristine
local FULL_ZVOL_NAME=${POOL_NAME}/${ZVOL_NAME}
local FULL_SNAP_NAME=${POOL_NAME}/${ZVOL_NAME}@${SNAP_NAME}
local SRC_DIR=/bin/
local TMP_CACHE=`mktemp -p /tmp zpool.cache.XXXXXXXX`
# Create a pool and volume.
${ZFS_SH} zfs="spa_config_path=${TMP_CACHE}" || fail 1
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 || fail 2
${ZFS} create -V 400M ${FULL_ZVOL_NAME} || fail 3
# Partition the volume, for a 400M volume there will be
# 812 cylinders, 16 heads, and 63 sectors per track.
zconfig_partition /dev/${FULL_ZVOL_NAME} 0 812
# Format the partition with ext2 (no journal).
/sbin/mkfs.ext2 -q /dev/${FULL_ZVOL_NAME}1 || fail 5
# Mount the ext3 filesystem and copy some data to it.
mkdir -p /tmp/${ZVOL_NAME}1 || fail 6
mount /dev/${FULL_ZVOL_NAME}1 /tmp/${ZVOL_NAME}1 || fail 7
# Snapshot the pristine ext2 filesystem and mount it read-only.
${ZFS} snapshot ${FULL_SNAP_NAME} || fail 8
wait_udev /dev/${FULL_SNAP_NAME}1 30 || fail 8
mkdir -p /tmp/${SNAP_NAME}1 || fail 9
mount /dev/${FULL_SNAP_NAME}1 /tmp/${SNAP_NAME}1 &>/dev/null || fail 10
# Copy to original volume
cp -RL ${SRC_DIR} /tmp/${ZVOL_NAME}1 || fail 11
sync
# Verify the copied files match the original files,
# and the copied files do NOT appear in the snapshot.
diff -ur ${SRC_DIR} /tmp/${ZVOL_NAME}1${SRC_DIR} &>/dev/null || fail 12
diff -ur ${SRC_DIR} /tmp/${SNAP_NAME}1${SRC_DIR} &>/dev/null && fail 13
# umount, destroy the snapshot, volume, and pool.
umount /tmp/${SNAP_NAME}1 || fail 14
rmdir /tmp/${SNAP_NAME}1 || fail 15
${ZFS} destroy ${FULL_SNAP_NAME} || fail 16
umount /tmp/${ZVOL_NAME}1 || fail 17
rmdir /tmp/${ZVOL_NAME}1 || fail 18
${ZFS} destroy ${FULL_ZVOL_NAME} || fail 19
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 -d || fail 20
${ZFS_SH} -u || fail 21
rm -f ${TMP_CACHE} || fail 22
pass
}
run_test 6 "zvol+ext2 snapshot"
# ZVOL clone sanity check
test_7() {
local POOL_NAME=tank
local ZVOL_NAME=fish
local SNAP_NAME=pristine
local CLONE_NAME=clone
local FULL_ZVOL_NAME=${POOL_NAME}/${ZVOL_NAME}
local FULL_SNAP_NAME=${POOL_NAME}/${ZVOL_NAME}@${SNAP_NAME}
local FULL_CLONE_NAME=${POOL_NAME}/${CLONE_NAME}
local SRC_DIR=/bin/
local TMP_CACHE=`mktemp -p /tmp zpool.cache.XXXXXXXX`
# Create a pool and volume.
${ZFS_SH} zfs="spa_config_path=${TMP_CACHE}" || fail 1
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 || fail 2
${ZFS} create -V 300M ${FULL_ZVOL_NAME} || fail 3
# Partition the volume, for a 300M volume there will be
# 609 cylinders, 16 heads, and 63 sectors per track.
zconfig_partition /dev/${FULL_ZVOL_NAME} 0 609
# Format the partition with ext2 (no journal).
/sbin/mkfs.ext2 -q /dev/${FULL_ZVOL_NAME}1 || fail 5
# Mount the ext3 filesystem and copy some data to it.
mkdir -p /tmp/${ZVOL_NAME}1 || fail 6
mount /dev/${FULL_ZVOL_NAME}1 /tmp/${ZVOL_NAME}1 || fail 7
# Snapshot the pristine ext2 filesystem and mount it read-only.
${ZFS} snapshot ${FULL_SNAP_NAME} || fail 8
wait_udev /dev/${FULL_SNAP_NAME}1 30 || fail 8
mkdir -p /tmp/${SNAP_NAME}1 || fail 9
mount /dev/${FULL_SNAP_NAME}1 /tmp/${SNAP_NAME}1 &>/dev/null || fail 10
# Copy to original volume.
cp -RL ${SRC_DIR} /tmp/${ZVOL_NAME}1 || fail 11
sync
# Verify the copied files match the original files,
# and the copied files do NOT appear in the snapshot.
diff -ur ${SRC_DIR} /tmp/${ZVOL_NAME}1${SRC_DIR} &>/dev/null || fail 12
diff -ur ${SRC_DIR} /tmp/${SNAP_NAME}1${SRC_DIR} &>/dev/null && fail 13
# Clone from the original pristine snapshot
${ZFS} clone ${FULL_SNAP_NAME} ${FULL_CLONE_NAME} || fail 14
wait_udev /dev/${FULL_CLONE_NAME}1 30 || fail 14
mkdir -p /tmp/${CLONE_NAME}1 || fail 15
mount /dev/${FULL_CLONE_NAME}1 /tmp/${CLONE_NAME}1 || fail 16
# Verify the clone matches the pristine snapshot,
# and the files copied to the original volume are NOT there.
diff -ur /tmp/${SNAP_NAME}1 /tmp/${CLONE_NAME}1 &>/dev/null || fail 17
diff -ur /tmp/${ZVOL_NAME}1 /tmp/${CLONE_NAME}1 &>/dev/null && fail 18
# Copy to cloned volume.
cp -RL ${SRC_DIR} /tmp/${CLONE_NAME}1 || fail 19
sync
# Verify the clone matches the modified original volume.
diff -ur /tmp/${ZVOL_NAME}1 /tmp/${CLONE_NAME}1 &>/dev/null || fail 20
# umount, destroy the snapshot, volume, and pool.
umount /tmp/${CLONE_NAME}1 || fail 21
rmdir /tmp/${CLONE_NAME}1 || fail 22
${ZFS} destroy ${FULL_CLONE_NAME} || fail 23
umount /tmp/${SNAP_NAME}1 || fail 24
rmdir /tmp/${SNAP_NAME}1 || fail 25
${ZFS} destroy ${FULL_SNAP_NAME} || fail 26
umount /tmp/${ZVOL_NAME}1 || fail 27
rmdir /tmp/${ZVOL_NAME}1 || fail 28
${ZFS} destroy ${FULL_ZVOL_NAME} || fail 29
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 -d || fail 30
${ZFS_SH} -u || fail 31
rm -f ${TMP_CACHE} || fail 32
pass
}
run_test 7 "zvol+ext2 clone"
# Send/Receive sanity check
test_8() {
local POOL_NAME1=tank1
local POOL_NAME2=tank2
local ZVOL_NAME=fish
local SNAP_NAME=snap
local FULL_ZVOL_NAME1=${POOL_NAME1}/${ZVOL_NAME}
local FULL_ZVOL_NAME2=${POOL_NAME2}/${ZVOL_NAME}
local FULL_SNAP_NAME1=${POOL_NAME1}/${ZVOL_NAME}@${SNAP_NAME}
local FULL_SNAP_NAME2=${POOL_NAME2}/${ZVOL_NAME}@${SNAP_NAME}
local SRC_DIR=/bin/
local TMP_CACHE=`mktemp -p /tmp zpool.cache.XXXXXXXX`
# Create two pools and a volume
${ZFS_SH} zfs="spa_config_path=${TMP_CACHE}" || fail 1
${ZPOOL_CREATE_SH} -p ${POOL_NAME1} -c lo-raidz2 || fail 2
${ZPOOL_CREATE_SH} -p ${POOL_NAME2} -c lo-raidz2 || fail 3
${ZFS} create -V 300M ${FULL_ZVOL_NAME1} || fail 4
# Partition the volume, for a 300M volume there will be
# 609 cylinders, 16 heads, and 63 sectors per track.
zconfig_partition /dev/${FULL_ZVOL_NAME1} 0 609
# Format the partition with ext2.
/sbin/mkfs.ext2 -q /dev/${FULL_ZVOL_NAME1}1 || fail 5
# Mount the ext3 filesystem and copy some data to it.
mkdir -p /tmp/${FULL_ZVOL_NAME1}1 || fail 6
mount /dev/${FULL_ZVOL_NAME1}1 /tmp/${FULL_ZVOL_NAME1}1 || fail 7
cp -RL ${SRC_DIR} /tmp/${FULL_ZVOL_NAME1}1 || fail 8
sync || fail 9
# Snapshot the ext3 filesystem so it may be sent.
${ZFS} snapshot ${FULL_SNAP_NAME1} || fail 11
wait_udev /dev/${FULL_SNAP_NAME1} 30 || fail 11
# Send/receive the snapshot from POOL_NAME1 to POOL_NAME2
(${ZFS} send ${FULL_SNAP_NAME1} | \
${ZFS} receive ${FULL_ZVOL_NAME2}) || fail 12
wait_udev /dev/${FULL_ZVOL_NAME2}1 30 || fail 12
# Mount the sent ext3 filesystem.
mkdir -p /tmp/${FULL_ZVOL_NAME2}1 || fail 13
mount /dev/${FULL_ZVOL_NAME2}1 /tmp/${FULL_ZVOL_NAME2}1 || fail 14
# Verify the contents of the volumes match
diff -ur /tmp/${FULL_ZVOL_NAME1}1 /tmp/${FULL_ZVOL_NAME2}1 \
&>/dev/null || fail 15
# Umount, destroy the volume and pool.
umount /tmp/${FULL_ZVOL_NAME1}1 || fail 16
umount /tmp/${FULL_ZVOL_NAME2}1 || fail 17
rmdir /tmp/${FULL_ZVOL_NAME1}1 || fail 18
rmdir /tmp/${FULL_ZVOL_NAME2}1 || fail 19
rmdir /tmp/${POOL_NAME1} || fail 20
rmdir /tmp/${POOL_NAME2} || fail 21
${ZFS} destroy ${FULL_SNAP_NAME1} || fail 22
${ZFS} destroy ${FULL_SNAP_NAME2} || fail 23
${ZFS} destroy ${FULL_ZVOL_NAME1} || fail 24
${ZFS} destroy ${FULL_ZVOL_NAME2} || fail 25
${ZPOOL_CREATE_SH} -p ${POOL_NAME1} -c lo-raidz2 -d || fail 26
${ZPOOL_CREATE_SH} -p ${POOL_NAME2} -c lo-raidz2 -d || fail 27
${ZFS_SH} -u || fail 28
rm -f ${TMP_CACHE} || fail 29
pass
}
run_test 8 "zfs send/receive"
# zpool event sanity check
test_9() {
local POOL_NAME=tank
local ZVOL_NAME=fish
local FULL_NAME=${POOL_NAME}/${ZVOL_NAME}
local TMP_CACHE=`mktemp -p /tmp zpool.cache.XXXXXXXX`
local TMP_EVENTS=`mktemp -p /tmp zpool.events.XXXXXXXX`
# Create a pool and volume.
${ZFS_SH} zfs="spa_config_path=${TMP_CACHE}" || fail 1
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 || fail 2
${ZFS} create -V 300M ${FULL_NAME} || fail 3
# Dump the events, there should be at least 5 lines.
${ZPOOL} events >${TMP_EVENTS} || fail 4
EVENTS=`wc -l ${TMP_EVENTS} | cut -f1 -d' '`
[ $EVENTS -lt 5 ] && fail 5
# Clear the events and ensure there are none.
${ZPOOL} events -c >/dev/null || fail 6
${ZPOOL} events >${TMP_EVENTS} || fail 7
EVENTS=`wc -l ${TMP_EVENTS} | cut -f1 -d' '`
[ $EVENTS -gt 1 ] && fail 8
${ZFS} destroy ${FULL_NAME} || fail 9
${ZPOOL_CREATE_SH} -p ${POOL_NAME} -c lo-raidz2 -d || fail 10
${ZFS_SH} -u || fail 11
rm -f ${TMP_CACHE} || fail 12
rm -f ${TMP_EVENTS} || fail 13
pass
}
run_test 9 "zpool events"
exit 0