cdaf906d68
Signed-off-by: David Sterba <dsterba@suse.com> |
||
---|---|---|
.. | ||
cli-tests | ||
convert-tests | ||
fsck-tests | ||
fuzz-tests | ||
misc-tests | ||
mkfs-tests | ||
build-tests.sh | ||
clean-tests.sh | ||
cli-tests.sh | ||
common | ||
common.convert | ||
common.local | ||
convert-tests.sh | ||
export-testsuite.sh | ||
fsck-tests.sh | ||
fssum.c | ||
fuzz-tests.sh | ||
ioctl-test.c | ||
library-test.c | ||
misc-tests.sh | ||
mkfs-tests.sh | ||
README.md | ||
scan-results.sh | ||
test-console.sh | ||
testsuite-files |
Btrfs-progs tests
A testsuite covering functionality of btrfs-progs, ie. the checker, image, mkfs
and similar tools. There are no additional requirements on kernel features
(other than CONFIG_BTRFS_FS
built-in or module), the
tests build on top of the core functionality like snapshots and device
management. In some cases optional features are turned on by mkfs and the
filesystem image could be mounted, such tests might fail if there's lack of
support.
Quick start
Run the tests from the top directory:
$ make test
$ make test-fsck
$ make test-convert
or selectively from the tests/
directory:
$ ./fsck-tests.sh
$ ./misc-tests.sh
The verbose output of the tests is logged into a file named after the test
category, eg. fsck-tests-results.txt
.
Selective testing
The tests are prefixed by a number for ordering and uniqueness. To run a particular test use:
$ make TEST=MASK test
where MASK
is a glob expression that will execute only tests
that match the MASK. Here the test number comes handy:
$ make TEST=001\* test-fsck # in tests/
$ TEST=001\* ./fsck-tests.sh # in the top directory
will run the first test in fsck-tests subdirectory. If the test directories follow a good naming scheme, it's possible to select a subset eg. like the convert tests for ext[234] filesystems using mask 'TEST='ext[234]'.
Test directory structure
tests/fsck-tests/
- tests targeted at bugs that are fixable by fsck, the test directory can
contain images that will get fixed, or a custom script
./test.sh
that will be run if present
tests/convert-tests/
- coverage tests of ext2/3/4 or reiserfs and btrfs-convert options
tests/fuzz-tests/
- collection of fuzzed or crafted images
- tests that are supposed to run various utilities on the images and not crash
tests/cli-tests/
- tests for command line interface, option coverage, weird option combinations that should not work
- not necessary to do any functional testing, could be rather lightweight
- functional tests should go to other test directories
- the driver script will only execute
./test.sh
in the test directory
tests/misc-tests/
- anything that does not fit to the above, the test driver script will only
execute
./test.sh
in the test directory
tests/common, tests/common.convert
- scripts with shell helpers, separated by functionality
tests/test.img
- default testing image, available as
TEST_DEV
variable, the file is never deleted by the scripts but truncated to 0 bytes, so it keeps it's permissions. It's eg. possible to host it on NFS, make itchmod a+w
for root.
Other tuning, environment variables
Instrumentation
It's possible to wrap the tested commands to utilities that might do more
checking or catch failures at runtime. This can be done by setting the
INSTRUMENT
environment variable:
make INSTRUMENT=valgrind test-fuzz # in the top directory
INSTRUMENT=valgrind ./fuzz-tests.sh # in tests/
The variable is prepended to the command unquoted, all sorts of shell tricks are possible.
Note: instrumentation is not applied to privileged commands (anything that uses the root helper), with exception of all commands built from git that will be instrumented even if run with the sudo helper.
run_check $SUDO_HELPER mount /dev/sdx /mnt # no instrumentation
run_check $SUDO_HELPER "$TOP/btrfs" check /dev/sdx # with instrumentation
Instrumented commands: btrfs, btrfs-image, btrfs-convert, btrfs-tune, mkfs.btrfs, btrfs-select-super, btrfs-find-root, btrfs-corrupt-block.
As mentioned above, instrumentation tools are like valgrind
or potentially
gdb
with some init script that will let the commands run until an exception
occurs, possibly allowing to continue interactively debugging.
Verbosity, test tuning
-
TEST_LOG=tty
-- setting the variable will print all commands executed by some of the wrappers (run_check
etc), other commands are not printed to the terminal (but the full output is in the log) -
TEST_LOG=dump
-- dump the entire testing log when a test fails -
TEST_ENABLE_OVERRIDE
-- defined either as make arguments or viatests/common.local
to enable additional arguments to some commands, using the variable(s) below (default: false, enable by setting to 'true') -
TEST_ARGS_CHECK
-- user-defined arguments tobtrfs check
, before the test-specific arguments -
TEST_ARGS_MKFS
-- user-defined arguments tomkfs.btrfs
, before the test-specific arguments -
TEST_ARGS_CONVERT
-- user-defined arguments tobtrfs-convert
, before the test-specific arguments
Multiple values can be separated by ,
.
For example, running all fsck tests with the --mode=lowmem
option can be done
as
$ make TEST_ENABLE_OVERRIDE=true TEST_ARGS_CHECK=--mode=lowmem test-check
Specifically, fsck-tests that are known to be able to repair images in the
lowmem mode shoulde be marked using a file .lowmem_repairable
in the test
directory. Then the fsck-tests with the 'mode=lowmem' will continue when image
repair is requested.
Permissions
Some commands require root privileges (to mount/umount, access loop devices or
call privileged ioctls). It is assumed that sudo
will work in some way (no
password, password asked and cached). Note that instrumentation is not applied
in this case, for safety reasons or because the tools refuse to run under root.
You need to modify the test script instead.
Cleanup
The tests are supposed to cleanup after themselves if they pass. In case of failure, the rest of the tests are skipped and intermediate files, mounts and loop devices are kept. This should help to investigate the test failure but at least the mounts and loop devices need to be cleaned before the next run.
This is partially done by the script clean-tests.sh
, you may want to check
the loop devices as they are managed on a per-test basis, see the output of
command losetup
and eventually delete all existing loop devices with losetup -D
.
Prototyping tests, quick tests
There's a script test-console.sh
that will run shell commands in a loop and
logs the output with the testing environment set up. It sources the common
helper scripts so the shell functions are available.
Runtime dependencies
The tests use some common system utilities like find
, rm
, dd
. Additionally,
specific tests need the following packages installed: acl
, attr
,
e2fsprogs
, reiserfsprogs
.
New test
-
Pick the category for the new test or fallback to
misc-tests
if not sure. For an easy start copy an existingtest.sh
script from some test that might be close to the purpose of your new test. The environment setup includes the common scripts and/or prepares the test devices. Other scripts contain examples how to do mkfs, mount, unmount, check, loop device management etc. -
Use the highest unused number in the sequence, write a short descriptive title and join by dashes
-
. This will become the directory name, eg.012-subvolume-sync-must-wait
. -
Write a short description of the bug and how it's tested to the comment at the beginning of
test.sh
. You don't need to add the file to git yet. Don't forget to make the file executable, otherwise it's not going to be executed by the infrastructure. -
Write the test commands, comment anything that's not obvious.
-
Test your test. Use the
TEST
variable to jump right to your test:
$ make TEST=012\* tests-misc # from top directory
$ TEST=012\* ./misc-tests.sh # from tests/
-
The commit changelog should reference a commit that either introduced or fixed the bug (or both). Subject line of the shall mention the name of the new directory for ease of search, eg.
btrfs-progs: tests: add 012-subvolume-sync-must-wait
-
A commit that fixes a bug should be applied before the test that verifies the fix. This is to keep the git history bisectable.
Test images
Most tests should be able to create the test images from scratch, using regular commands and file operation. The commands also document the testcase and use the test code and kernel of the environment.
In other cases, a pre-created image may be the right way if the above does not work (eg. comparing output, requesting an exact layout or some intermediate state that would be hard to achieve otherwise).
-
images that don't need data and valid checksums can be created by
btrfs-image
, the image can be compressed by the tool itself (file extension.img
) or compressed externally (recognized is.img.xz
) -
raw images that are binary dump of an existing image, created eg. from a sparse file (
.raw
or.raw.xz
)
Use xz --best
and try to get the smallest size as the file is stored in git.
Crafted/fuzzed images
Images that are created by fuzzing or specially crafted to trigger some error conditions should be added to the directory fuzz-tests/images, accompanied by a textual description of the source (bugzilla, mail), the reporter, brief description of the problem or the stack trace.
If you have a fix for the problem, please submit it prior to the test image, so the fuzz tests always succeed when run on random checked out. This helps bisectability.
Exported testsuite
The tests are typically run from git on binaries built from the git sources. It is possible to extract only the testsuite files and run it independently. Use
$ make testsuite
This will gather scripts and generate tests/btrfs-progs-tests.tar.gz
. The
files inside the tar are in the top level directory, make sure you extract
the contents to an empty directory. From there you can start the tests as
described above (the non-make variant).
By default the binaries found in $PATH
are used, this will normally mean the
system binaries. You can also override the $TOP
shell variable and this
path will be used as prefix for all btrfs binaries inside the tests.
There are some utilities that are not distributed but are necessary for the tests. They are in the top level directory of the testsuite and their path cannot be set.
The tests assume write access to their directories.
Coding style, best practices
do
- quote all variables by default, any path, even the TOP could need that, and
we use it everywhere
- even if the variable is safe, use quotes for consistency and to ease reading the code
- there are exceptions:
$SUDO_HELPER
as it might be intentionally unset
- use
#!/bin/bash
explicitly - check for all external dependencies (
check_prereq_global
) - check for internal dependencies (
check_prereq
), though the basic set is always built when the tests are started through make - use functions instead of repeating code
- generic helpers could be factored to the
common
script
- generic helpers could be factored to the
- cleanup files an intermediate state (mount, loop devices, device mapper devices) a after successful test
- use common helpers and variables where possible
do not
- pull external dependencies if we can find a way to replace them: example is
xfs_io
that's conveniently used in fstests but we'd requirexfsprogs
, so usedd
instead - throw away (redirect to /dev/null) output of commands unless it's justified (ie. really too much text, unnecessary slowdown) -- the test output log is regenerated all the time and we need to be able to analyze test failures or just observe how the tests progress
- cleanup after failed test -- the testsuite stops on first failure and the
developer can eg. access the environment that the test created and do further
debugging
- this might change in the future so the tests cover as much as possible, but this would require to enhance all tests with a cleanup phase
Simple test template
The file tests/common
provides shell functions to ease writing common things
like setting up the test devices, making or mounting a filesystem, setting up
loop devices.
#!/bin/bash
# Simple test to create a new filesystem and test that it can be mounted
source "$TEST_TOP/common"
setup_root_helper
prepare_test_dev
run_check_mkfs_test_dev
run_check_mount_test_dev
run_check $SUDO_HELPER dd if=/dev/zero of="$TEST_MNT"/file bs=1M count=1
run_check_umount_test_dev
Each test should be briefly described, source the helpers like run_check
. The
root helper is the sudo
wrapper that can be used as $SUDO_HELPER
variable.
The implicit variables for testing device is $TEST_DEV
mounted at $TEST_MNT
.
The mkfs and mount helpers take arguments that are then injected into the right
place in the respective command.
Besides the setup and cleanup code, the main test in this example is dd
that
writes 1MiB to a file in the newly created filesystem.
Multiple device test template
Tests that need more devices can utilize the loop devices, an example test of the above:
# Create a new multi-device filesystem and test that it can be mounted
source "$TEST_TOP/common"
setup_root_helper
setup_loopdevs 4
prepare_loopdevs
TEST_DEV=${loopdevs[1]}
run_check $SUDO_HELPER "$TOP/mkfs.btrfs" -f -d raid1 -m raid1 "${loopdevs[@]}"
run_check_mount_test_dev
run_check $SUDO_HELPER dd if=/dev/zero of="$TEST_MNT"/file bs=1M count=1
run_check_umount_test_dev
cleanup_loopdevs
A 'btrfs check' test template
The easiest way to test an image is to put it to the test directory, without
the test.sh
script. All images found are simply processed by the shell
function check_image
with default parameters.
Any tweaks to the 'check' subcommand can be done by redefining the function:
source "$TEST_TOP/common"
check_image() {
run_check "$TOP/btrfs" check --readonly "$1"
}
check_all_images
The images can be stored in various formats, see section 'Test images'.
Misc hints
There are several helpers in tests/common
, it's recommended to read through
that file or other tests to get the idea how easy writing a test really is.
- result
_fail
- a failure condition has been found_not_run
- some prerequisite condition is not met, eg. missing kernel functionality
- messages
_log
- message printed to the result file (eg.tests/mkfs-tests-results.txt
), and not printed to the terminal_log_stdout
- dtto but it is printed to the terminal
- execution helpers
run_check
- should be used for basically all commadns, the command and arguments are stored to the results log for debugging and the return value is checked so there are no silent failures even for the "unimportant" commandsrun_check_stdout
- like the above but the output can be processed further, eg. filtering out some data or looking for some specific stringrun_mayfail
- the command is allowed to fail in a non-fatal way (eg. no segfault), there's also therun_mayfail_stdout
variantrun_mustfail
- expected failure, note that the first argument is mandatory message describing unexpected pass condition