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Message-ID: <5edd8272-a2d5-028d-28da-de76a93f2fa4@digikod.net>
Date: Wed, 10 Mar 2021 19:13:33 +0100
From: Mickaël Salaün <mic@...ikod.net>
To: "Eric W. Biederman" <ebiederm@...ssion.com>
Cc: Al Viro <viro@...iv.linux.org.uk>,
James Morris <jmorris@...ei.org>,
Serge Hallyn <serge@...lyn.com>,
Andy Lutomirski <luto@...capital.net>,
Christian Brauner <christian.brauner@...ntu.com>,
Christoph Hellwig <hch@....de>,
David Howells <dhowells@...hat.com>,
Dominik Brodowski <linux@...inikbrodowski.net>,
John Johansen <john.johansen@...onical.com>,
Kees Cook <keescook@...omium.org>,
Kentaro Takeda <takedakn@...data.co.jp>,
Tetsuo Handa <penguin-kernel@...ove.sakura.ne.jp>,
kernel-hardening@...ts.openwall.com, linux-fsdevel@...r.kernel.org,
linux-kernel@...r.kernel.org,
linux-security-module@...r.kernel.org,
Mickaël Salaün <mic@...ux.microsoft.com>
Subject: Re: [PATCH v1 1/1] fs: Allow no_new_privs tasks to call chroot(2)
On 10/03/2021 17:56, Eric W. Biederman wrote:
> Mickaël Salaün <mic@...ikod.net> writes:
>
>> From: Mickaël Salaün <mic@...ux.microsoft.com>
>>
>> Being able to easily change root directories enable to ease some
>> development workflow and can be used as a tool to strengthen
>> unprivileged security sandboxes. chroot(2) is not an access-control
>> mechanism per se, but it can be used to limit the absolute view of the
>> filesystem, and then limit ways to access data and kernel interfaces
>> (e.g. /proc, /sys, /dev, etc.).
>
> Actually chroot does not so limit the view of things. It only limits
> the default view.
>
> A process that is chrooted can always escape by something like
> chroot("../../../../../../../../..").
Not with this patch.
>
> So I don't see the point of allowing chroot once you are in your locked
> down sandbox.
>
>> Users may not wish to expose namespace complexity to potentially
>> malicious processes, or limit their use because of limited resources.
>> The chroot feature is much more simple (and limited) than the mount
>> namespace, but can still be useful. As for containers, users of
>> chroot(2) should take care of file descriptors or data accessible by
>> other means (e.g. current working directory, leaked FDs, passed FDs,
>> devices, mount points, etc.). There is a lot of literature that discuss
>> the limitations of chroot, and users of this feature should be aware of
>> the multiple ways to bypass it. Using chroot(2) for security purposes
>> can make sense if it is combined with other features (e.g. dedicated
>> user, seccomp, LSM access-controls, etc.).
>>
>> One could argue that chroot(2) is useless without a properly populated
>> root hierarchy (i.e. without /dev and /proc). However, there are
>> multiple use cases that don't require the chrooting process to create
>> file hierarchies with special files nor mount points, e.g.:
>> * A process sandboxing itself, once all its libraries are loaded, may
>> not need files other than regular files, or even no file at all.
>> * Some pre-populated root hierarchies could be used to chroot into,
>> provided for instance by development environments or tailored
>> distributions.
>> * Processes executed in a chroot may not require access to these special
>> files (e.g. with minimal runtimes, or by emulating some special files
>> with a LD_PRELOADed library or seccomp).
>>
>> Allowing a task to change its own root directory is not a threat to the
>> system if we can prevent confused deputy attacks, which could be
>> performed through execution of SUID-like binaries. This can be
>> prevented if the calling task sets PR_SET_NO_NEW_PRIVS on itself with
>> prctl(2). To only affect this task, its filesystem information must not
>> be shared with other tasks, which can be achieved by not passing
>> CLONE_FS to clone(2). A similar no_new_privs check is already used by
>> seccomp to avoid the same kind of security issues. Furthermore, because
>> of its security use and to avoid giving a new way for attackers to get
>> out of a chroot (e.g. using /proc/<pid>/root), an unprivileged chroot is
>> only allowed if the new root directory is the same or beneath the
>> current one. This still allows a process to use a subset of its
>> legitimate filesystem to chroot into and then further reduce its view of
>> the filesystem.
>>
>> This change may not impact systems relying on other permission models
>> than POSIX capabilities (e.g. Tomoyo). Being able to use chroot(2) on
>> such systems may require to update their security policies.
>>
>> Only the chroot system call is relaxed with this no_new_privs check; the
>> init_chroot() helper doesn't require such change.
>>
>> Allowing unprivileged users to use chroot(2) is one of the initial
>> objectives of no_new_privs:
>> https://www.kernel.org/doc/html/latest/userspace-api/no_new_privs.html
>> This patch is a follow-up of a previous one sent by Andy Lutomirski, but
>> with less limitations:
>> https://lore.kernel.org/lkml/0e2f0f54e19bff53a3739ecfddb4ffa9a6dbde4d.1327858005.git.luto@amacapital.net/
>
> Last time I remember talking architecture we agreed that user namespaces
> would be used for enabling features and that no_new_privs would just be
> used to lock-down userspace. That way no_new_privs could be kept simple
> and trivial to audit and understand.
chroot(2) is simple.
>
> You can build your sandbox and use chroot if you use a user namespace at
> the start. A mount namespace would also help lock things down. Still
> allowing chroot after the sanbox has been built, a seccomp filter has
> been installed and no_new_privs has been enabled seems like it is asking
> for trouble and may weaken existing sandboxes.
Could you please provide a new attack scenario?
>
> So I think we need a pretty compelling use case to consider allowing
> chroot(2). You haven't even mentioned what your usecase is at this
> point so I don't know why we would tackle that complexity.
They are explained in this commit message.
>
> Eric
>
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