nixpkgs/nixos/tests/systemd-confinement/checkperms.py
aszlig 51d3f3475c
nixos/tests/confinement: Run test probes in Python
So far the architecture for the tests was that we would use a systemd
socket unit using the Accept option to start a small shell process where
we can pipe commands into by connecting to the socket created by the
socket unit.

This is unnecessary since we can directly use the code snippets from the
individual subtests and systemd will take care of checking the return
code in case we get any assertions[^1].

Another advantage of this is that tests now run in parallel, so we can
do rather expensive things such as looking in /nix to see whether
anything is writable.

The new assert_permissions() function is the main driver behind this and
allows for a more fine-grained way to check whether we got the right
permissions whilst also ignoring irrelevant things such as read-only
empty directories.

Our previous approach also just did a read-only check, which might be
fine in full-apivfs mode where the attack surface already is large, but
in chroot-only mode we really want to make sure nothing is every
writable.

A downside of the new approach is that currently the unit names are
numbered via lib.imap1, which makes it annoying to track its definition.

[^1]: Speaking of assertions, I wrapped the code to be run with pytest's
      assertion rewriting, so that we get more useful AssertionErrors.

Signed-off-by: aszlig <aszlig@nix.build>
2024-05-13 00:40:36 +02:00

188 lines
6.4 KiB
Python

import errno
import os
from enum import IntEnum
from pathlib import Path
class Accessibility(IntEnum):
"""
The level of accessibility we have on a file or directory.
This is needed to assess the attack surface on the file system namespace we
have within a confined service. Higher levels mean more permissions for the
user and thus a bigger attack surface.
"""
NONE = 0
# Directories can be listed or files can be read.
READABLE = 1
# This is for special file systems such as procfs and for stuff such as
# FIFOs or character special files. The reason why this has a lower value
# than WRITABLE is because those files are more restricted on what and how
# they can be written to.
SPECIAL = 2
# Another special case are sticky directories, which do allow write access
# but restrict deletion. This does *not* apply to sticky directories that
# are read-only.
STICKY = 3
# Essentially full permissions, the kind of accessibility we want to avoid
# in most cases.
WRITABLE = 4
def assert_on(self, path: Path) -> None:
"""
Raise an AssertionError if the given 'path' allows for more
accessibility than 'self'.
"""
actual = self.NONE
if path.is_symlink():
actual = self.READABLE
elif path.is_dir():
writable = True
dummy_file = path / 'can_i_write'
try:
dummy_file.touch()
except OSError as e:
if e.errno in [errno.EROFS, errno.EACCES]:
writable = False
else:
raise
else:
dummy_file.unlink()
if writable:
# The reason why we test this *after* we made sure it's
# writable is because we could have a sticky directory where
# the current user doesn't have write access.
if path.stat().st_mode & 0o1000 == 0o1000:
actual = self.STICKY
else:
actual = self.WRITABLE
else:
actual = self.READABLE
elif path.is_file():
try:
with path.open('rb') as fp:
fp.read(1)
actual = self.READABLE
except PermissionError:
pass
writable = True
try:
with path.open('ab') as fp:
fp.write('x')
size = fp.tell()
fp.truncate(size)
except PermissionError:
writable = False
except OSError as e:
if e.errno == errno.ETXTBSY:
writable = os.access(path, os.W_OK)
elif e.errno == errno.EROFS:
writable = False
else:
raise
# Let's always try to fail towards being writable, so if *either*
# access(2) or a real write is successful it's writable. This is to
# make sure we don't accidentally introduce no-ops if we have bugs
# in the more complicated real write code above.
if writable or os.access(path, os.W_OK):
actual = self.WRITABLE
else:
# We need to be very careful when writing to or reading from
# special files (eg. FIFOs), since they can possibly block. So if
# it's not a file, just trust that access(2) won't lie.
if os.access(path, os.R_OK):
actual = self.READABLE
if os.access(path, os.W_OK):
actual = self.SPECIAL
if actual > self:
stat = path.stat()
details = ', '.join([
f'permissions: {stat.st_mode & 0o7777:o}',
f'uid: {stat.st_uid}',
f'group: {stat.st_gid}',
])
raise AssertionError(
f'Expected at most {self!r} but got {actual!r} for path'
f' {path} ({details}).'
)
def is_special_fs(path: Path) -> bool:
"""
Check whether the given path truly is a special file system such as procfs
or sysfs.
"""
try:
if path == Path('/proc'):
return (path / 'version').read_text().startswith('Linux')
elif path == Path('/sys'):
return b'Linux' in (path / 'kernel' / 'notes').read_bytes()
except FileNotFoundError:
pass
return False
def is_empty_dir(path: Path) -> bool:
try:
next(path.iterdir())
return False
except (StopIteration, PermissionError):
return True
def _assert_permissions_in_directory(
directory: Path,
accessibility: Accessibility,
subdirs: dict[Path, Accessibility],
) -> None:
accessibility.assert_on(directory)
for file in directory.iterdir():
if is_special_fs(file):
msg = f'Got unexpected special filesystem at {file}.'
assert subdirs.pop(file) == Accessibility.SPECIAL, msg
elif not file.is_symlink() and file.is_dir():
subdir_access = subdirs.pop(file, accessibility)
if is_empty_dir(file):
# Whenever we got an empty directory, we check the permission
# constraints on the current directory (except if specified
# explicitly in subdirs) because for example if we're non-root
# (the constraints of the current directory are thus
# Accessibility.READABLE), we really have to make sure that
# empty directories are *never* writable.
subdir_access.assert_on(file)
else:
_assert_permissions_in_directory(file, subdir_access, subdirs)
else:
subdirs.pop(file, accessibility).assert_on(file)
def assert_permissions(subdirs: dict[str, Accessibility]) -> None:
"""
Recursively check whether the file system conforms to the accessibility
specification we specified via 'subdirs'.
"""
root = Path('/')
absolute_subdirs = {root / p: a for p, a in subdirs.items()}
_assert_permissions_in_directory(
root,
Accessibility.WRITABLE if os.getuid() == 0 else Accessibility.READABLE,
absolute_subdirs,
)
for file in absolute_subdirs.keys():
msg = f'Expected {file} to exist, but it was nowwhere to be found.'
raise AssertionError(msg)