Re: [RFC PATCH 0/3] memfd: cleanups for vm.memfd_noexec
From: Jeff Xu
Date: Wed Aug 02 2023 - 15:55:07 EST
On Wed, Aug 2, 2023 at 12:47 PM Jeff Xu <jeffxu@xxxxxxxxxxxx> wrote:
>
> On Tue, Aug 1, 2023 at 6:05 PM Aleksa Sarai <cyphar@xxxxxxxxxx> wrote:
> >
> This thread is getting longer with different topics, I will try to
> respond with trimmed interleaved replies [1]
> There are 3 topics (logging/'migration/ratcheting), this response will
> be regarding ratcheting.
>
> [1] https://www.kernel.org/doc/html/latest/process/submitting-patches.html?highlight=signed%20off#use-trimmed-interleaved-replies-in-email-discussions
>
> >
> > > > > > * The ratcheting mechanism for vm.memfd_noexec doesn't make sense as a
> > > > > > security mechanism because a CAP_SYS_ADMIN capable user can create
> > > > > > executable binaries in a hidden tmpfs very easily, not to mention the
> > > > > > many other things they can do.
> > > > > >
> > > > > By further limiting CAP_SYS_ADMIN, an attacker can't modify this
> > > > > sysctl even after compromising some system service with high
> > > > > privilege, YAMA has the same approach for ptrace_scope=3
> > > >
> > > > Personally, I also think this behaviour from YAMA is a little goofy too,
> > > > but given that it only locks the most extreme setting and there is no
> > > > way to get around the most extreme setting, I guess it makes some sense
> > > > (not to mention it's an LSM and so there is an argument that it should
> > > > be possible to lock out privileged users from modifying it).
> > > > There are many other security sysctls, and very few have this behaviour
> > > > because it doesn't make much sense in most cases.
> > > >
> > > > > In addition, this sysctl is pid_name spaced, this means child
> > > > > pid_namespace will alway have the same or stricter security setting
> > > > > than its parent, this allows admin to maintain a tree like view. If we
> > > > > allow the child pid namespace to elevate its setting, then the
> > > > > system-wide setting is no longer meaningful.
> > > >
> > > > "no longer meaningful" is too strong of a statement imho. It is still
> > > > useful for constraining non-root processes and presumably ChromeOS
> > > > disallows random processes to do CLONE_NEWUSER (otherwise the protection
> > > > of this sysctl is pointless) so in practice for ChromeOS there is no
> > > > change in the attack surface.
> > > >
> > > > (FWIW, I think tying this to the user namespace would've made more sense
> > > > since this is about privilege restrictions, but that ship has sailed.)
> > > >
> > > The reason that this sysctl is a PID namespace is that I hope a
> > > container and host can have different sysctl values, e.g. host will
> > > allow runc's use of X mfd, while a container doesn't want X mfd. .
> > > To clarify what you meant, do you mean this: when a container is in
> > > its own pid_namespace, and has "=2", the programs inside the container
> > > can still use CLONE_NEWUSER to break out "=2" ?
> >
> > With the current implementation, this is not possible. My point was that
> > even if it were possible to lower the sysctl, ChromeOS presumably
> > already blocks the operations that a user would be able to use to create
> > a memfd (an unprivileged user cannot CLONE_NEWPID to modify the sysctl
> > without CLONE_NEWUSER, which is presumably blocked on ChromeOS due to
> > the other security concerns).
> >
> >
> > > > > The code sample shared in this patch set indicates that the attacker
> > > > > already has the ability of creating tmpfs and executing complex steps,
> > > > > at that point, it doesn't matter if the code execution is from memfd
> > > > > or not. For a safe by default system such as ChromeOS, attackers won't
> > > > > easily run arbitrary code, memfd is one of the open doors for that, so
> > > > > we are disabling executable memfd in ChromeOS. In other words: if an
> > > > > attacker can already execute the arbitrary code as sample given in
> > > > > ChromeOS, without using executable memfd, then memfd is no longer the
> > > > > thing we need to worry about, the arbitrary code execution is already
> > > > > achieved by the attacker. Even though I use ChromeOS as an example, I
> > > > > think the same type of threat model applies to any system that wants
> > > > > to disable executable memfd entirely.
> > > >
> > > > I understand the threat model this sysctl is blocking, my point is that
> > > > blocking CAP_SYS_ADMIN from modifying the setting doesn't make sense
> > > > from that threat model. An attacker that manages to trick some process
> > > > into creating a memfd with an executable payload is not going to be able
> > > > to change the sysctl setting (unless there's a confused deputy with
> > > > CAP_SYS_ADMIN, in which case you have much bigger issues).
> > > >
> > > It is the reverse. An attacker that manages to trick some
> > > CAP_SYSADMIN processes into changing this sysctl value (i.e. lower the
> > > setting to 0 if no ratcheting), will be able to continue to use mfd as
> > > part of the attack chain.
> > > In chromeOS, an attacker that can change sysctl might not necessarily
> > > gain full arbitrary code execution already. As I mentioned previously,
> > > the main threat model here is to prevent arbitrary code execution
> > > through mfd. If an attacker already gains arbitrary code execution,
> > > at that point, we no longer worry about mfd.
> >
> > If an attacker can trick a privileged process into writing to arbitrary
> > sysctls, the system has much bigger issues than arbitrary (presumably
> > unprivileged) code execution. On the other hand, requiring you to reboot
> > a server due to a misconfigured sysctl *is* broken.
> >
> > Again, at the very least, not even allowing capable(CAP_SYS_ADMIN) to
> > change the setting is actually broken.
> >
> > > > If a CAP_SYS_ADMIN-capable user wants to change the sysctl, blocking it
> > > > doesn't add any security because that process could create a memfd-like
> > > > fd to execute without issues.
> > > >What practical attack does this ratcheting
> > > > mechanism protect against? (This is a question you can answer with the
> > > > YAMA sysctl, but not this one AFAICS.)
> > > >
> > > > But even if you feel that allowing this in child user namespaces is
> > > > unsafe or undesirable, it's absolutely necessary that
> > > > capable(CAP_SYS_ADMIN) should be able to un-brick the running system by
> > > > changing the sysctl. The alternative is that you need to reboot your
> > > > server in order to un-set a sysctl that broke some application you run.
> > > >
> > >
> > > > Also, by the same token, this ratcheting mechanism doesn't make sense
> > > > with =1 *at all* because it could break programs in a way that would
> > > > require a reboot but it's not a "security setting" (and the YAMA sysctl
> > > > mentioned only locks the sysctl at the highest setting).
> > > >
> > > I think a system should use "=0" when it is unsure about its program's
> > > need or not need executable memfd. Technically, it is not that this
> > > sysctl breaks the user, but the admin made the mistake to set the
> > > wrong sysctl value, and an admin should know what they are doing for a
> > > sysctl. Yes. rebooting increases the steps to undo the mistake, but
> > > that could be an incentive for the admin to fully test its programs
> > > before turning on this sysctl - and avoid unexpected runtime errors.
> >
> > I don't think this stance is really acceptable -- if an admin that has
> > privileges to load kernel modules is not able to disable a sysctl that
> > can break working programs without rebooting there is
> >
> > When this sysctl was first proposed a few years ago (when kernel folks
> > found out that runc was using executable memfds), my understanding is
> > that the long-term goal was to switch programs to have
> > non-executable-memfds by default on most distributions. Making it
> > impossible for an admin to lower the sysctl value flies in the face of
> > this goal.
> >
> > At the very least, being unable to lower the sysctl from =1 to =0 is
> > just broken (even if you use the yama example -- yama only locks the
> > sysctl at highest possible setting, not on lower settings). But in my
> > view, having this sysctl ratchet at all doesn't make sense.
> >
> To reiterate/summarize the current mechanism for vm.memfd_noexec
>
> 1> It is a pid namespace sysctl, init ns and child pid ns can have
> different setting values.
> 2> child pid ns inherits parent's pid ns's sysctl at the time of fork.
> 3> There are 3 values for the sysctl, each higher value is more
> restrictive than the lower one. Once set, doesn't allow downgrading.
>
> It can be used as following:
> 1>
> init ns: vm.memfd_noexec = 2 (at boot time)
> Not allow executable memfd for the entire system, including its containers.
>
> 2>
> init ns: vm.memfd_noexec = 0 or 1
> container (child init namespace) vm.memfd_noexec = 2.
> The host allows runc's usage of executable memfd during container
> creation. Inside the container, executable memfd is not allowed.
>
> The inherence + not allow downgrading is to reason with how
> vm.memfd_noexec is applied in the process tree.
> Without it, essentially we are losing the hierarchy view across the
> process tree and a process can evaluate its capability by modifying
*elevate*
> the setting. I think that is a less secure approach I would not
> prefer.
>
> Thanks
>
> -Jeff