On 2023-07-19, Jeff Xu jeffxu@google.com wrote:
On Tue, Jul 18, 2023 at 8:10 PM Aleksa Sarai cyphar@cyphar.com wrote:
On 2023-07-17, Jeff Xu jeffxu@chromium.org wrote:
Hello Aleksa,
Thanks for your email and patches for discussion.
On Thu, Jul 13, 2023 at 7:34 AM Aleksa Sarai cyphar@cyphar.com wrote:
It seems that the most critical issue with vm.memfd_noexec=2 (the fact that passing MFD_EXEC would bypass it entirely[1]) has been fixed in Andrew's tree[2], but there are still some outstanding issues that need to be addressed:
- The dmesg warnings are pr_warn_once, which on most systems means that they will be used up by systemd or some other boot process and userspace developers will never see it. The original patch posted to the ML used pr_warn_ratelimited but the merged patch had it changed (with a comment about it being "per review"), but given that the current warnings are useless, pr_warn_ratelimited makes far more sense.
Ya, This was discussed in [1] Replacing pr_warn_once with pr_warn_ratelimited won't address Peter Xu's observation that "ratelimited" will fill syslog [2], I'm not sure it is acceptable to ones who is not interested in memfd, I will defer this to maintainers.
[1] https://lore.kernel.org/lkml/202212161233.85C9783FB@keescook/ [2] https://lwn.net/ml/linux-kernel/Y5yS8wCnuYGLHMj4@x1n/
I see Kees's point, but in that case the logging should be tied to the sysctl being the non-default value (I can post this version next if you prefer). The current logging setup doesn't make sense.
Is there a best practice in kernel for this problem: too much log vs too little log In other products, usually the log level or compiler flag (ifdef) are for such a situation.
It depends on what the purpose of the warning is -- if the purpose of the warning is to tell developers to migrate their programs, then a rate-limited warning is the only reasonable behaviour.
pr_warn_ratelimited() is the most straight-forward way of doing the warning. There are alternatives (the pids cgroup has a per-cgroup warning that is only triggered the first time a fork() fails in that cgroup) -- but the key point is that the log will appear in dmesg in a way that a developer will be able to notice. Having a single warning at the very beginning of the boot sequence is useless. On my system, systemd does memfd_create() without the new flags, so all you see is the following message:
[ 1.531305] memfd_create() without MFD_EXEC nor MFD_NOEXEC_SEAL, pid=1 'systemd'
in the middle of all of the other stuff that gets spit out during boot. This obviously is going to be missed by basically all users.
- vm.memfd_noexec=2 shouldn't reject old-style memfd_create(2) syscalls because it will make it far to difficult to ever migrate. Instead it should imply MFD_EXEC.
Though the purpose of memfd_noexec=2 is not to help with migration - but to disable creation of executable memfd for the current system/pid namespace. During the migration, vm.memfd_noexe = 1 helps overwriting for unmigrated user code as a temporary measure.
My point is that the current behaviour for =2 means that nobody other than *maybe* ChromeOS will ever be able to use it because it requires auditing every program on the system. In fact, it's possible even ChromeOS will run into issues given that one of the arguments made for the nosymfollow mount option was that auditing all of ChromeOS to replace every open with RESOLVE_NO_SYMLINKS would be too much effort[1] (which I agreed with). Maybe this is less of an issue with memfd_create(2) (which is much newer than open(2)) but it still seems like a lot of busy work when the =1 behaviour is entirely sane even in the strict threat model that =2 is trying to protect against.
It can also be a container (that have all memfd_create migrated to new API)
If ChromeOS would struggle to rewrite all of the libraries they use, containers are in even worse shape -- most container users don't have a complete list of every package installed in a container, let alone the ability to audit whether they pass a (no-op) flag to memfd_create(2) in every codepath.
One option I considered previously was "=2" would do overwrite+block , and "=3" just block. But then I worry that applications won't have motivation to ever change their existing code, the setting will forever stay at "=2", making "=3" even more impossible to ever be used system side.
What is the downside of overwriting? Backwards-compatibility is a very important part of Linux -- being able to use old programs without having to modify them is incredibly important. Yes, this behaviour is opt-in -- but I don't see the point of making opting in more difficult than necessary. Surely overwite+block provides the security guarantee you need from the threat model -- othewise nobody will be able to use block because you never know if one library will call memfd_create() "incorrectly" without the new flags.
To me, using =1 as a migration path (and in fact, calling =1 a migration path further argues that the warning for not setting _EXEC or _NOEXEC_SEAL should be tied to =1) would mean finding every program that uses executable memfds and changing it to stop doing that. Not that you use =1 to go and rewrite every userspace program that uses memfd_create(2) at all, without using executable memfds (rebooting each time to test the behaviour because we use pr_warn_once).
I tend to think logging and sysctl are orthogonal, tie them together making it more complex than necessary. If we need more logging, we should find what is the best practice in the kernel for that.
See my above comment -- tying it to >= 1 would alleviate the log spam concerns. pr_warn_once() is useless for this purpose.
If you want to block syscalls that don't explicitly pass NOEXEC_SEAL, there are several tools for doing this (both seccomp and LSM hooks).
Additional functionality/features should be implemented through security hook and LSM, not sysctl, I think.
This issue with =2 cannot be fixed in an LSM. (On the other hand, you could implement either =2 behaviour with an LSM using =1, and the current strict =2 behaviour could be implemented purely with seccomp.)
By migration, I mean a system that is not fully migrated, such a system should just use "=0" or "=1". Additional features can be implemented in SELinux/Landlock/other LSM by a motivated dev. e.g. if a system wants to limit executable memfd to specific programs or fully disable it. "=2" is for a system/container that is fully migrated, in that case, SELinux/Landlock/LSM can do the same, but sysctl provides a convenient alternative. Yes, seccomp provides a similar mechanism. Indeed, combining "=1" and seccomp (block MFD_EXEC), it will overwrite + block X mfd, which is essentially what you want, iiuc.However, I do not wish to have this implemented in kernel, due to the thinking that I want kernel to get out of business of "overwriting" eventually.
See my above comments -- "overwriting" is perfectly acceptable to me. There's also no way to "get out of the business of overwriting" -- Linux has strict backwards compatibility requirements.
- 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).
And what makes the user namespace a better choice than pid namespace for this sysctl ?
It's too late for this discussion, the sysctl has already shipped and you can't change this behaviour anymore.
However, the simple reason is that the kernel ties permission-related things to the user namespace because credentials are tied to the userns -- the only other pidns-related sysctl is kernel.ns_last_pid, which clearly needs to be tied to the pidns.
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.
Thanks! -Jeff