On Thu, 2023-07-06 at 05:53 -0500, Dr. Greg wrote: > On Tue, Jul 04, 2023 at 05:18:43PM +0200, Petr Tesarik wrote: > > Good morning, I hope the week is going well for everyone. > > > On 7/3/2023 5:28 PM, Roberto Sassu wrote: > > > On Mon, 2023-07-03 at 17:06 +0200, Jann Horn wrote: > > > > On Thu, Jun 22, 2023 at 4:45???PM Roberto Sassu > > > > <roberto.sassu@xxxxxxxxxxxxxxx> wrote: > > > > > I wanted to execute some kernel workloads in a fully isolated user > > > > > space process, started from a binary statically linked with klibc, > > > > > connected to the kernel only through a pipe. > > > > > > > > FWIW, the kernel has some infrastructure for this already, see > > > > CONFIG_USERMODE_DRIVER and kernel/usermode_driver.c, with a usage > > > > example in net/bpfilter/. > > > > > > Thanks, I actually took that code to make a generic UMD management > > > library, that can be used by all use cases: > > > > > > https://lore.kernel.org/linux-kernel/20230317145240.363908-1-roberto.sassu@xxxxxxxxxxxxxxx/ > > > > > > > > I also wanted that, for the root user, tampering with that process is > > > > > as hard as if the same code runs in kernel space. > > > > > > > > I believe that actually making it that hard would probably mean that > > > > you'd have to ensure that the process doesn't use swap (in other > > > > words, it would have to run with all memory locked), because root can > > > > choose where swapped pages are stored. Other than that, if you mark it > > > > as a kthread so that no ptrace access is allowed, you can probably get > > > > pretty close. But if you do anything like that, please leave some way > > > > (like a kernel build config option or such) to enable debugging for > > > > these processes. > > > > > > I didn't think about the swapping part... thanks! > > > > > > Ok to enable debugging with a config option. > > > > > > > But I'm not convinced that it makes sense to try to draw a security > > > > boundary between fully-privileged root (with the ability to mount > > > > things and configure swap and so on) and the kernel - my understanding > > > > is that some kernel subsystems don't treat root-to-kernel privilege > > > > escalation issues as security bugs that have to be fixed. > > > > > > Yes, that is unfortunately true, and in that case the trustworthy UMD > > > would not make things worse. On the other hand, on systems where that > > > separation is defined, the advantage would be to run more exploitable > > > code in user space, leaving the kernel safe. > > > > > > I'm thinking about all the cases where the code had to be included in > > > the kernel to run at the same privilege level, but would not use any of > > > the kernel facilities (e.g. parsers). > > > > Thanks for reminding me of kexec-tools. The complete image for booting a > > new kernel was originally prepared in user space. With kernel lockdown, > > all this code had to move into the kernel, adding a new syscall and lots > > of complexity to build purgatory code, etc. Yet, this new implementation > > in the kernel does not offer all features of kexec-tools, so both code > > bases continue to exist and are happily diverging... > > > > > If the boundary is extended to user space, some of these components > > > could be moved away from the kernel, and the functionality would be the > > > same without decreasing the security. > > > All right, AFAICS your idea is limited to relatively simple cases > > for now. I mean, allowing kexec-tools to run in user space is not > > easily possible when UID 0 is not trusted, because kexec needs to > > open various files and make various other syscalls, which would > > require a complex LSM policy. It looks technically possible to write > > one, but then the big question is if it would be simpler to review > > and maintain than adding more kexec-tools features to the kernel. > > You either need to develop and maintain a complex system-wide LSM > policy or you need a security model that is specifically tuned and > then scoped to the needs of the workload running on behalf of the > kernel as a UID=0 userspace process. > > As I noted in my e-mail to Roberto, our TSEM LSM brings forward the > ability to do both, as a useful side effect of the need to limit model > complexity when the objective is to have a single functional > description of the security state of a system. > > > Anyway, I can sense a general desire to run less code in the most > > privileged system environment. Robert's proposal is one of few that > > go in this direction. What are the alternatives? > > As I noted above, TSEM brings the ability to provide highly specific > and narrowly scoped security policy to a process heirarchy > ie. workload. > > However, regardless of the technology applied, in order to pursue > Roberto's UMD model of having a uid=0 process run tasks on behalf of > the kernel, there would seem to be a need to define what the security > objectives are. > > From the outside looking in, there would seem to be a need to address > two primary issues: > > 1: Trust/constrain what the UMD process can do. Very simple: read from a kernel-opened fd, write to another kernel-opened fd, close the fds and exit. With the seccomp strict profile, a process cannot call any other system call, and it gets killed if it does. I tried to write a BPF filter, to see how far I can go, and that seems sufficient to constrain what the UMD process can do. Please note that the UMD process setup is done by the kernel, before any user space code has the chance to run. The kernel is responsible to properly establish the communication with the UMD process. > 2: Constrain what the system at large can do to the UMD process. If someone outside can influence the behavior of the UMD process, meaning altering the result, that would be unacceptable. I found that denying ptrace on the UMD process as target, more or less covers everything, even trying to read or write /proc/<pid>/fd/<N>. There might be something more subtle, like what Iann pointed out, avoid swapping of the UMD process, as there is no integrity check when the page comes back. Other than that, I was limiting the kill, maybe we have to do something similar with io_uring (but we would know if the UMD process uses it). With that in place, the UMD process seems pretty much isolated. I would definitely not complicate things more than that, seems that this problem is already difficult enough to solve. Since the goal is very specific, I think writing a very small LSM would make sense. With SELinux or Smack, you could also do it, but you have to care about loading a policy, enforcing, etc.. The main question is if the kernel is able to enforce isolation on the UMD process as it would do for itself. I'm not considering confidentiality for now, just integrity. And with the most simple case of the UMD process only communicating with the kernel (sufficient for my use cases). > As we have seen before, requirement 1 implies a definition of what it > means for a process to be 'trusted'. > > In the absence of formal verification, which appears to be a > non-starter in practice, this would seem to imply defining a standard > for the allowed security behavior of the UMD workload. > > From our perspective, with TSEM, we define 'trusted' for a workload to > mean that it has not requested a security behavior inconsistent with > what the workload has been unit tested to. If a process does this, its > ability to execute additional security behaviors is curtailed. > > With respect to requirement two. > > Here is the ASCII art diagram of Roberto's proposed system: > > r/w ^ kernel space > ----------|----------------------------------------- > v (pipe) user space > +-----------------+ +-----------------------+ > | trustworthy UMD |---X---| rest of the processes | > +-----------------+ +-----------------------+ > > Casey noted that he believed the Linux LSM had sufficient coverage to > provide the necessary security controls for this model. He > specifically mentioned that it had support for network traffic > controls and labeling. > > I haven't seen a reply from Roberto to my e-mail questioning what the > following means: > > ---X--- That means no communication. Thanks Roberto > But I get the sense that it means that any other process in userspace > couldn't have any impact, or I assume visibility, into what the UID=0 > process is doing on behalf of the kernel. I don't think it means that > there is supposed to be some type of highly controlled traffic between > the UMD and other processes. > > We will see what comments Roberto has on this. > > This arguably may be the most difficult requirement to meet if our > interpretation of this requirement is correct, particularly so if this > involves a confidentiality requirement, perhaps a bit less so if there > is only a requirement of integrity of execution. > > As I mentioned in a previous e-mail, depending on the requirements, > issue 2 starts to look a lot like protected enclave technologies such > as SGX. As history has shown, providing a protected execution > environment, against the rest of the system, is a somewhat formidable > undertaking, with probably a requirement for hardware support if SGX > and/or TDX are any examples. > > So, I believe that TSEM brings useful technology to the table, but > regardless of technology, it would seem there is a need to > specifically define the security requirements for the UMD model. > > > Petr T > > Have a good day. > > As always, > Dr. Greg > > The Quixote Project - Flailing at the Travails of Cybersecurity