client/site_tests/platform_EncryptedStateful/platform_EncryptedStateful.py - mirrors/cros/chromiumos/third_party/autotest - Git at Google

 # Copyright (c) 2012 The Chromium OS Authors. All rights reserved.
 # Use of this source code is governed by a BSD-style license that can be
 # found in the LICENSE file.

 import logging, os, tempfile, shutil, stat, time, posix
 from autotest_lib.client.bin import test, utils
 from autotest_lib.client.common_lib import error

 # TODO:
 #  - mock out TPM and check all error conditions
 #  - test failure when things aren't mounted correctly

 class test_checker(object):
     def __init__(self):
         logging.info("test_checker.__init__")
         # Empty failure list means test passes.
         self._failures = []

     def _passed(self, msg):
         logging.info('ok: %s' % (msg))

     def _failed(self, msg):
         logging.error('FAIL: %s' % (msg))
         self._failures.append(msg)

     def _fatal(self, msg):
         logging.error('FATAL: %s' % (msg))
         raise error.TestError(msg)

     def check(self, boolean, msg, fatal=False):
         if boolean == True:
             self._passed(msg)
         else:
             msg = "could not satisfy '%s'" % (msg)
             if fatal:
                 self._fatal(msg)
             else:
                 self._failed(msg)

     def test_raise(self):
         # Raise a failure if anything unexpected was seen.
         if len(self._failures):
             raise error.TestFail((", ".join(self._failures)))

 chk = test_checker()


 class EncryptedStateful(object):
     def _prepare_simulated_root(self):
         os.makedirs(self.var)
         os.makedirs(self.chronos)
         os.makedirs(self.stateful)

         # Build fake stateful block device (emulate 10G sda1).
         self.stateful_block = os.path.join(self.root, 'stateful.block')
         utils.system("truncate -s 10G %s" % (self.stateful_block))
         utils.system("mkfs.ext4 -F %s" % (self.stateful_block))
         utils.system("mount -n -t ext4 -o loop,noatime,commit=600 %s %s" %
                      (self.stateful_block, self.stateful))

     def __init__(self, root=None):
         if root == None:
             self.root = tempfile.mkdtemp(dir='/mnt/stateful_partition',
                                          prefix='.test-enc-stateful-')
             self.simulated = True
         else:
             self.root = root
             self.simulated = False

         self.var = os.path.join(self.root, 'var')
         self.chronos = os.path.join(self.root, 'home', 'chronos')
         self.stateful = os.path.join(self.root, 'mnt', 'stateful_partition')
         self.mount_log = os.path.join(self.stateful, 'mount.log')
         self.key = os.path.join(self.stateful, 'encrypted.key')
         self.needs_finalization = os.path.join(self.stateful,
                                                'encrypted.needs-finalization')
         self.block = os.path.join(self.stateful, 'encrypted.block')
         self.encrypted = os.path.join(self.stateful, 'encrypted')

         if self.simulated:
             try:
                 self._prepare_simulated_root()
             except:
                 shutil.rmtree(self.root)
                 raise

         self.mounted = not self.simulated

     def mount(self, args=""):
         if self.mounted or not self.simulated:
             return
         # TODO(keescook): figure out what is killing the resizer and
         # remove the explicit use of "tee" here.
         # Without the pipe to "tee", mount-encrypted's forked resizing
         # process gets killed, even though it is using daemon(). (Is
         # autotest doing something odd here?) This leaves the filesystem
         # unresized. It would be better to have the resizer running in
         # the background, as it is designed, so we can examine its behavior
         # during testing (e.g. "does the filesystem actually grow?").
         utils.system("MOUNT_ENCRYPTED_ROOT=%s mount-encrypted %s 2>&1 "
                      "| tee %s" % (self.root, args, self.mount_log))
         self.mounted = True

     def umount(self):
         if not self.mounted or not self.simulated:
             return
         utils.system("MOUNT_ENCRYPTED_ROOT=%s mount-encrypted umount" %
                          (self.root))
         self.mounted = False

     # Clean up when destroyed.
     def __del__(self):
         if self.simulated:
             self.umount()
             utils.system("umount -n %s" % (self.stateful))
             shutil.rmtree(self.root)

     # Perform common post-mount size/owner checks on the filesystem and
     # backing files.
     def check_sizes(self, finalized=True):
         # Do we have the expected backing files?
         chk.check(os.path.exists(self.block), "%s exists" % (self.block))
         if finalized:
             keyfile = self.key
             other = self.needs_finalization
         else:
             keyfile = self.needs_finalization
             other = self.key
         chk.check(os.path.exists(keyfile), "%s exists" % (keyfile))
         chk.check(not os.path.exists(other), "%s does not exist" % (other))

         # Sanity check the key file stat.
         info = os.stat(keyfile)
         chk.check(stat.S_ISREG(info.st_mode),
                   "%s is regular file" % (keyfile))
         chk.check(info.st_uid == 0, "%s is owned by root" % (keyfile))
         chk.check(info.st_gid == 0, "%s has group root" % (keyfile))
         chk.check(stat.S_IMODE(info.st_mode) == (stat.S_IRUSR | stat.S_IWUSR),
                   "%s is S_IRUSR | S_IWUSR" % (keyfile))
         chk.check(info.st_size == 48, "%s is 48 bytes" % (keyfile))

         # Sanity check the block file stat.
         info = os.stat(self.block)
         chk.check(stat.S_ISREG(info.st_mode),
                   "%s is regular file" % (self.block))
         chk.check(info.st_uid == 0, "%s is owned by root" % (self.block))
         chk.check(info.st_gid == 0, "%s has group root" % (self.block))
         chk.check(stat.S_IMODE(info.st_mode) == (stat.S_IRUSR | stat.S_IWUSR),
                   "%s is S_IRUSR | S_IWUSR" % (self.block))
         # Make sure block file is roughly a third of the size of the root
         # filesystem (within 5%).
         top = os.statvfs(self.stateful)
         backing_size = float(info.st_size)
         third = top.f_blocks * top.f_frsize * .3
         chk.check(backing_size > (third * .95)
                   and backing_size < (third * 1.05),
                   "%s is near %d bytes (was %d)" % (self.block, third,
                                                     info.st_size))

         # Wait for resize manager task to finish.
         utils.poll_for_condition(lambda: utils.system("pgrep mount-encrypted",
                                                       ignore_status=True) != 0,
                                  error.TestError('resizer still running'))

         # Verify filesystem is within 5% of the block file size.
         info = os.statvfs(self.encrypted)
         encrypted_size = float(info.f_frsize) * float(info.f_blocks)
         chk.check(encrypted_size / backing_size > 0.95,
                   "%s fs (%d) is nearly the backing device size (%d)" %
                   (self.encrypted, encrypted_size, backing_size))
         # Verify there is a reasonable number of inodes in the encrypted
         # filesystem (near 25% inodes-to-blocks ratio).
         inode_ratio = float(info.f_files) / float(info.f_blocks)
         chk.check(inode_ratio > 0.20 and inode_ratio < 0.30,
                   "%s has close to 25%% ratio of inodes-to-blocks (%.2f%%)" %
                   (self.encrypted, inode_ratio*100))

         # Raise non-fatal failures now, if they were encountered.
         chk.test_raise()

     # Wait for kernel background writing to finish.
     def _backing_stabilize(self):
         start = None
         size = 0
         while True:
             k = long(utils.system_output("du -sk %s" % (self.block),
                                          retain_output = True).split()[0])
             if start == None:
                 start = k
             if k == size:
                 # Backing file has remained the same size for 10 seconds.
                 # Assume the kernel is done with background initialization.
                 break
             time.sleep(10)
             utils.system("sync")
             size = k
         logging.info("%s stabilized at %dK (was %dK)" %
                      (self.block, size, start))

     # Check that the backing file reclaims space when filesystem contents
     # are deleted.
     def check_reclamation(self):
         # This test is sensitive to other things happening on the filesystem,
         # so we must wait for background initialization to finish first.
         self._backing_stabilize()

         megs = 200
         data = os.path.join(self.var, "check_reclamation")
         orig = os.statvfs(self.stateful)

         # 200M file added to encrypted filesystem.
         utils.system("dd if=/dev/zero of=%s bs=1M count=%s; sync" % (data,
                                                                      megs))
         # Wait for background allocations to finish.
         self._backing_stabilize()
         filled = os.statvfs(self.stateful)

         # 200M file removed from encrypted filesystem.
         utils.system("rm %s; sync" % (data))
         # Wait for background hole-punching to finish.
         self._backing_stabilize()
         done = os.statvfs(self.stateful)

         # Did the underlying filesystem grow by the size of the test file?
         file_blocks_used = float((megs * 1024 * 1024) / orig.f_frsize)
         fs_blocks_used = float(orig.f_bfree - filled.f_bfree)
         chk.check(file_blocks_used / fs_blocks_used > 0.95,
                   "%d file blocks account for most of %d fs blocks" %
                   (file_blocks_used, fs_blocks_used))

         # Did the underlying filesystem shrink on removal?
         fs_blocks_done = float(orig.f_bfree - done.f_bfree)
         chk.check(fs_blocks_done / file_blocks_used < 0.05,
                   "most of %d fs blocks reclaimed (%d fs blocks left over, "
                   "free: %d -> %d -> %d)" %
                   (fs_blocks_used, fs_blocks_done,
                    orig.f_bfree, filled.f_bfree, done.f_bfree))

         # Raise non-fatal failures now, if they were encountered.
         chk.test_raise()


 class platform_EncryptedStateful(test.test):
     version = 1

     def existing_partition(self):
         # Examine the existing encrypted partition.
         encstate = EncryptedStateful("/")

         # Perform post-mount sanity checks (and handle unfinalized devices).
         encstate.check_sizes(finalized=os.path.exists(encstate.key))

     def factory_key(self):
         # Create test root directory.
         encstate = EncryptedStateful()

         # Make sure we haven't run here before.
         chk.check(not os.path.exists(encstate.key),
                   "%s does not exist" % (encstate.key))
         chk.check(not os.path.exists(encstate.block),
                   "%s does not exist" % (encstate.block))

         # Mount a fresh encrypted stateful, with factory static key.
         encstate.mount("factory")

         # Perform post-mount sanity checks.
         encstate.check_sizes()

         # Check disk reclamation.
         encstate.check_reclamation()

         # Check explicit umount.
         encstate.umount()

     def no_tpm(self):
         encstate = EncryptedStateful()

         # Relocate the TPM device during mount.
         tpm = "/dev/tpm0"
         off = "%s.off" % (tpm)
         try:
             if os.path.exists(tpm):
                 utils.system("mv %s %s" % (tpm, off))
             # Mount without a TPM.
             encstate.mount()
         finally:
             if os.path.exists(off):
                 utils.system("mv %s %s" % (off, tpm))

         # Perform post-mount sanity checks.
         encstate.check_sizes(finalized=False)

     def run_once(self):
         # Do a no-write test of system's existing encrypted partition.
         self.existing_partition()

         # Do a no-write, no-TPM test with sanity checks.
         self.no_tpm()

         # There is no interactively controllable TPM mock yet for
         # mount-encrypted, so we can only test the static key currently.
         self.factory_key()
	# Copyright (c) 2012 The Chromium OS Authors. All rights reserved.
	# Use of this source code is governed by a BSD-style license that can be
	# found in the LICENSE file.

	import logging, os, tempfile, shutil, stat, time, posix
	from autotest_lib.client.bin import test, utils
	from autotest_lib.client.common_lib import error

	# TODO:
	# - mock out TPM and check all error conditions
	# - test failure when things aren't mounted correctly

	class test_checker(object):
	def __init__(self):
	logging.info("test_checker.__init__")
	# Empty failure list means test passes.
	self._failures = []

	def _passed(self, msg):
	logging.info('ok: %s' % (msg))

	def _failed(self, msg):
	logging.error('FAIL: %s' % (msg))
	self._failures.append(msg)

	def _fatal(self, msg):
	logging.error('FATAL: %s' % (msg))
	raise error.TestError(msg)

	def check(self, boolean, msg, fatal=False):
	if boolean == True:
	self._passed(msg)
	else:
	msg = "could not satisfy '%s'" % (msg)
	if fatal:
	self._fatal(msg)
	else:
	self._failed(msg)

	def test_raise(self):
	# Raise a failure if anything unexpected was seen.
	if len(self._failures):
	raise error.TestFail((", ".join(self._failures)))

	chk = test_checker()


	class EncryptedStateful(object):
	def _prepare_simulated_root(self):
	os.makedirs(self.var)
	os.makedirs(self.chronos)
	os.makedirs(self.stateful)

	# Build fake stateful block device (emulate 10G sda1).
	self.stateful_block = os.path.join(self.root, 'stateful.block')
	utils.system("truncate -s 10G %s" % (self.stateful_block))
	utils.system("mkfs.ext4 -F %s" % (self.stateful_block))
	utils.system("mount -n -t ext4 -o loop,noatime,commit=600 %s %s" %
	(self.stateful_block, self.stateful))

	def __init__(self, root=None):
	if root == None:
	self.root = tempfile.mkdtemp(dir='/mnt/stateful_partition',
	prefix='.test-enc-stateful-')
	self.simulated = True
	else:
	self.root = root
	self.simulated = False

	self.var = os.path.join(self.root, 'var')
	self.chronos = os.path.join(self.root, 'home', 'chronos')
	self.stateful = os.path.join(self.root, 'mnt', 'stateful_partition')
	self.mount_log = os.path.join(self.stateful, 'mount.log')
	self.key = os.path.join(self.stateful, 'encrypted.key')
	self.needs_finalization = os.path.join(self.stateful,
	'encrypted.needs-finalization')
	self.block = os.path.join(self.stateful, 'encrypted.block')
	self.encrypted = os.path.join(self.stateful, 'encrypted')

	if self.simulated:
	try:
	self._prepare_simulated_root()
	except:
	shutil.rmtree(self.root)
	raise

	self.mounted = not self.simulated

	def mount(self, args=""):
	if self.mounted or not self.simulated:
	return
	# TODO(keescook): figure out what is killing the resizer and
	# remove the explicit use of "tee" here.
	# Without the pipe to "tee", mount-encrypted's forked resizing
	# process gets killed, even though it is using daemon(). (Is
	# autotest doing something odd here?) This leaves the filesystem
	# unresized. It would be better to have the resizer running in
	# the background, as it is designed, so we can examine its behavior
	# during testing (e.g. "does the filesystem actually grow?").
	utils.system("MOUNT_ENCRYPTED_ROOT=%s mount-encrypted %s 2>&1 "
	"\| tee %s" % (self.root, args, self.mount_log))
	self.mounted = True

	def umount(self):
	if not self.mounted or not self.simulated:
	return
	utils.system("MOUNT_ENCRYPTED_ROOT=%s mount-encrypted umount" %
	(self.root))
	self.mounted = False

	# Clean up when destroyed.
	def __del__(self):
	if self.simulated:
	self.umount()
	utils.system("umount -n %s" % (self.stateful))
	shutil.rmtree(self.root)

	# Perform common post-mount size/owner checks on the filesystem and
	# backing files.
	def check_sizes(self, finalized=True):
	# Do we have the expected backing files?
	chk.check(os.path.exists(self.block), "%s exists" % (self.block))
	if finalized:
	keyfile = self.key
	other = self.needs_finalization
	else:
	keyfile = self.needs_finalization
	other = self.key
	chk.check(os.path.exists(keyfile), "%s exists" % (keyfile))
	chk.check(not os.path.exists(other), "%s does not exist" % (other))

	# Sanity check the key file stat.
	info = os.stat(keyfile)
	chk.check(stat.S_ISREG(info.st_mode),
	"%s is regular file" % (keyfile))
	chk.check(info.st_uid == 0, "%s is owned by root" % (keyfile))
	chk.check(info.st_gid == 0, "%s has group root" % (keyfile))
	chk.check(stat.S_IMODE(info.st_mode) == (stat.S_IRUSR \| stat.S_IWUSR),
	"%s is S_IRUSR \| S_IWUSR" % (keyfile))
	chk.check(info.st_size == 48, "%s is 48 bytes" % (keyfile))

	# Sanity check the block file stat.
	info = os.stat(self.block)
	chk.check(stat.S_ISREG(info.st_mode),
	"%s is regular file" % (self.block))
	chk.check(info.st_uid == 0, "%s is owned by root" % (self.block))
	chk.check(info.st_gid == 0, "%s has group root" % (self.block))
	chk.check(stat.S_IMODE(info.st_mode) == (stat.S_IRUSR \| stat.S_IWUSR),
	"%s is S_IRUSR \| S_IWUSR" % (self.block))
	# Make sure block file is roughly a third of the size of the root
	# filesystem (within 5%).
	top = os.statvfs(self.stateful)
	backing_size = float(info.st_size)
	third = top.f_blocks * top.f_frsize * .3
	chk.check(backing_size > (third * .95)
	and backing_size < (third * 1.05),
	"%s is near %d bytes (was %d)" % (self.block, third,
	info.st_size))

	# Wait for resize manager task to finish.
	utils.poll_for_condition(lambda: utils.system("pgrep mount-encrypted",
	ignore_status=True) != 0,
	error.TestError('resizer still running'))

	# Verify filesystem is within 5% of the block file size.
	info = os.statvfs(self.encrypted)
	encrypted_size = float(info.f_frsize) * float(info.f_blocks)
	chk.check(encrypted_size / backing_size > 0.95,
	"%s fs (%d) is nearly the backing device size (%d)" %
	(self.encrypted, encrypted_size, backing_size))
	# Verify there is a reasonable number of inodes in the encrypted
	# filesystem (near 25% inodes-to-blocks ratio).
	inode_ratio = float(info.f_files) / float(info.f_blocks)
	chk.check(inode_ratio > 0.20 and inode_ratio < 0.30,
	"%s has close to 25%% ratio of inodes-to-blocks (%.2f%%)" %
	(self.encrypted, inode_ratio*100))

	# Raise non-fatal failures now, if they were encountered.
	chk.test_raise()

	# Wait for kernel background writing to finish.
	def _backing_stabilize(self):
	start = None
	size = 0
	while True:
	k = long(utils.system_output("du -sk %s" % (self.block),
	retain_output = True).split()[0])
	if start == None:
	start = k
	if k == size:
	# Backing file has remained the same size for 10 seconds.
	# Assume the kernel is done with background initialization.
	break
	time.sleep(10)
	utils.system("sync")
	size = k
	logging.info("%s stabilized at %dK (was %dK)" %
	(self.block, size, start))

	# Check that the backing file reclaims space when filesystem contents
	# are deleted.
	def check_reclamation(self):
	# This test is sensitive to other things happening on the filesystem,
	# so we must wait for background initialization to finish first.
	self._backing_stabilize()

	megs = 200
	data = os.path.join(self.var, "check_reclamation")
	orig = os.statvfs(self.stateful)

	# 200M file added to encrypted filesystem.
	utils.system("dd if=/dev/zero of=%s bs=1M count=%s; sync" % (data,
	megs))
	# Wait for background allocations to finish.
	self._backing_stabilize()
	filled = os.statvfs(self.stateful)

	# 200M file removed from encrypted filesystem.
	utils.system("rm %s; sync" % (data))
	# Wait for background hole-punching to finish.
	self._backing_stabilize()
	done = os.statvfs(self.stateful)

	# Did the underlying filesystem grow by the size of the test file?
	file_blocks_used = float((megs * 1024 * 1024) / orig.f_frsize)
	fs_blocks_used = float(orig.f_bfree - filled.f_bfree)
	chk.check(file_blocks_used / fs_blocks_used > 0.95,
	"%d file blocks account for most of %d fs blocks" %
	(file_blocks_used, fs_blocks_used))

	# Did the underlying filesystem shrink on removal?
	fs_blocks_done = float(orig.f_bfree - done.f_bfree)
	chk.check(fs_blocks_done / file_blocks_used < 0.05,
	"most of %d fs blocks reclaimed (%d fs blocks left over, "
	"free: %d -> %d -> %d)" %
	(fs_blocks_used, fs_blocks_done,
	orig.f_bfree, filled.f_bfree, done.f_bfree))

	# Raise non-fatal failures now, if they were encountered.
	chk.test_raise()


	class platform_EncryptedStateful(test.test):
	version = 1

	def existing_partition(self):
	# Examine the existing encrypted partition.
	encstate = EncryptedStateful("/")

	# Perform post-mount sanity checks (and handle unfinalized devices).
	encstate.check_sizes(finalized=os.path.exists(encstate.key))

	def factory_key(self):
	# Create test root directory.
	encstate = EncryptedStateful()

	# Make sure we haven't run here before.
	chk.check(not os.path.exists(encstate.key),
	"%s does not exist" % (encstate.key))
	chk.check(not os.path.exists(encstate.block),
	"%s does not exist" % (encstate.block))

	# Mount a fresh encrypted stateful, with factory static key.
	encstate.mount("factory")

	# Perform post-mount sanity checks.
	encstate.check_sizes()

	# Check disk reclamation.
	encstate.check_reclamation()

	# Check explicit umount.
	encstate.umount()

	def no_tpm(self):
	encstate = EncryptedStateful()

	# Relocate the TPM device during mount.
	tpm = "/dev/tpm0"
	off = "%s.off" % (tpm)
	try:
	if os.path.exists(tpm):
	utils.system("mv %s %s" % (tpm, off))
	# Mount without a TPM.
	encstate.mount()
	finally:
	if os.path.exists(off):
	utils.system("mv %s %s" % (off, tpm))

	# Perform post-mount sanity checks.
	encstate.check_sizes(finalized=False)

	def run_once(self):
	# Do a no-write test of system's existing encrypted partition.
	self.existing_partition()

	# Do a no-write, no-TPM test with sanity checks.
	self.no_tpm()

	# There is no interactively controllable TPM mock yet for
	# mount-encrypted, so we can only test the static key currently.
	self.factory_key()