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There are a number of desired Linux Kernel hardening projects that are inactive and do not have an owner.  This page gives details on some of them.  If you have an update for this page, please email the kernel-hardening mailing list at kernel-hardening@lists.openwall.com.
The [[Linux Security Workgroup]] has put together this page in an effort to bring the Linux security community together in hardening the Linux Kernel and to help prevent duplication of efforts.  There are a number of desired Linux Kernel hardening projects listed below that are inactive and do not have an owner.


= Process Improvements =
= Process Improvements =
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* Kernel build infrastructure
* Kernel build infrastructure


This could include approaches such as manual audits, static analysis, fuzzing testing, etc.
This could include approaches such as manual audits, static analysis, fuzz testing, etc.


= Development =
= Development =


There are several kernel hardening features that have appeared in other hardened operating systems that would improve the security of Linux. Some have been controversial, so attempts have been made to describe them, including their controversy and discussion over the years, so as much information is available to make an educated decision about potential implementations.
There are several kernel hardening features that have appeared in other hardened operating systems that would improve the security of Linux. Some have been controversial, so attempts have been made to describe them, including their controversy and discussion over the years, so as much information is available to make an educated decision about potential implementations.
== Symlink Protection ==
A long-standing class of security issues is the symlink-based [http://en.wikipedia.org/wiki/Time-of-check-to-time-of-use ToCToU] race, most commonly seen in world-writable directories like /tmp/. The common method of exploitation of [http://cve.mitre.org/cgi-bin/cvekey.cgi?keyword=tmp+symlink this flaw] is crossing privilege boundaries when following a given symlink (i.e. a root user follows a symlink belonging to another user).
The solution is to not permit symlinks to be followed when users do not match, but only in a world-writable sticky directory (with an additional improvement that the directory owner's symlinks can always be followed, regardless who is following them).
Some links to the history of its discussion:
* 1996 Aug, Zygo Blaxell http://marc.info/?l=bugtraq&m=87602167419830&w=2
* 1996 Oct, Andrew Tridgell http://lkml.indiana.edu/hypermail/linux/kernel/9610.2/0086.html
* 1997 Dec, Albert D Cahalan http://lkml.org/lkml/1997/12/16/4
* 2005 Feb, Lorenzo Hernández García-Hierro http://lkml.indiana.edu/hypermail/linux/kernel/0502.0/1896.html
Past objections and rebuttals could be summarized as:
* Violates POSIX.
** POSIX didn't consider this situation, and it's not useful to follow a broken specification at the cost of security. Also, please reference where POSIX says this.
* Might break unknown applications that use this feature.
** Applications that break because of the change are easy to spot and fix. Applications that are vulnerable to symlink ToCToU by not having the change aren't.
* Applications should just use mkstemp() or O_CREATE|O_EXCL.
** True, but applications are not perfect, and new software is written all the time that makes these mistakes; blocking this flaw at the kernel is a single solution to the entire class of vulnerability.
[https://lists.ubuntu.com/archives/kernel-team/2010-May/010491.html initial proposed patch]
[http://kernel.ubuntu.com/git?p=kees/linux-2.6.git;a=shortlog;h=refs/heads/symlink proposed upstream patch]
== Hardlink Protection ==
Hardlinks can be abused in a [http://cve.mitre.org/cgi-bin/cvekey.cgi?keyword=hardlink similar fashion] to symlinks above, but they are not limited to world-writable directories. If /etc/ and /home/ are on the same partition, a regular user can create a hardlink to /etc/shadow in their home directory. While it retains the original owner and permissions, it is possible for privileged programs that are otherwise symlink-safe to mistakenly access the file through its hardlink. Additionally, a very minor untraceable quota-bypassing local denial of service is possible by an attacker exhausting disk space by filling a world-writable directory with hardlinks.
The solution is to not allow the creation of hardlinks to files that a given user would be unable to write to originally.
Some links to the history of its discussion:
* 1997 Dec, Yuri Kuzmenko http://lkml.org/lkml/1997/12/29/20
* 2002 Apr, Chris Wright http://lkml.org/lkml/2002/4/13/99
Past objections and rebuttals could be summarized as:
* Violates POSIX.
** POSIX didn't consider this situation, and it's not useful to follow a broken specification at the cost of security. Also, please reference where POSIX says this.
* Might break atd, courier, and other unknown applications that use this feature.
** These applications are easy to spot and can be tested and fixed. Applications that are vulnerable to hardlink attacks by not having the change aren't.
** atd could be easily "repaired" by including a real uid==0 check, like Linux 2.4.x-ow does for that reason, or it might have been fixed since then, or better yet [http://cvsweb.openwall.com/cgi/cvsweb.cgi/Owl/packages/vixie-cron/ OpenBSD-derived crond] should be used instead, which includes at(1) support (and it never had the problem with hardlinks). The latter solution also gets rid of a SUID root program (at(1) is SGID to group crontab then) and of a root-privileged daemon (cron and atd are replaced with just one crond).
** Courier was only broken by the original most restrictive -ow patch; it was "repaired" in newer -ow patch revisions by adding the "or is writable by the current user" check, which is also present in the proposed patches below (in other words, Courier won't break with these patches)
* Applications should correctly drop privileges before attempting to access user files.
** True, but applications are not perfect, and new software is written all the time that makes these mistakes; blocking this flaw at the kernel is a single solution to the entire class of vulnerability.
[https://lists.ubuntu.com/archives/kernel-team/2010-May/010495.html initial proposed patch]
[http://kernel.ubuntu.com/git?p=kees/linux-2.6.git;a=shortlog;h=refs/heads/hardlink proposed upstream patch]
== ptrace Protection ==
As Linux grows in popularity, it will become a growing target for malware. One particularly troubling weakness of the Linux process interfaces is that a single user is able to examine the memory and running state of any of their processes. For example, if one application (e.g. firefox) was compromised, it would be possible for an attacker to attach to other running processes (e.g. gpg-agent) to extract additional credentials and continue to expand the scope of their attack.
This is not a theoretical problem. [http://www.storm.net.nz/projects/7 SSH session hijacking] and even [http://c-skills.blogspot.com/2009/10/injectso-32bit-x86-port.html arbitrary code injection] is fully possible if ptrace is allowed normally.
For a solution, some applications use prctl() to specifically disallow such ptrace attachment (e.g. ssh-agent). A more general solution is to only allow ptrace directly from a parent to a child process (i.e. direct gdb and strace still work), or as the root user (i.e. gdb BIN PID, and strace -p PID still work as root).
This behavior is controlled via the /proc/sys/kernel/yama/ptrace_scope sysctl value. The default is "1" to block non-child ptrace. A value of "0" restores the prior more permissive behavior, which may be more appropriate for some development systems and servers with only admin accounts. Using "sudo" can also grant temporarily ptrace permissions via the CAP_SYS_PTRACE capability, though this method allows the ptrace of any process.
[https://lists.ubuntu.com/archives/kernel-team/2010-May/010499.html initial proposed patch]
[http://kernel.ubuntu.com/git?p=kees/linux-2.6.git;a=shortlog;h=refs/heads/ptrace proposed upstream patch]


== Partial NX Emulation ==
== Partial NX Emulation ==
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== Additional Kernel Hardening Development Projects ==
== Additional Kernel Hardening Development Projects ==
Here is a rough plan for things to do to the upstream Linux kernel to make it harder for security vulnerabilities to become exploitable.
Following are more upstream Linux kernel projects that would make it harder for security vulnerabilities to become exploitable.


Note: Many CONFIG_* items below refer to PaX and grsecurity.
Note: Many CONFIG_* items below refer to PaX and grsecurity.
* ASLR for kernel code (Dan Rosenberg: IN PROGRESS)
* remove remaining kernel address leaks that prevent ASLR from being effective
* remove remaining kernel address leaks that prevent ASLR from being effective (Dan Rosenberg)
** https://patchwork.kernel.org/patch/487751/
** https://patchwork.kernel.org/patch/487751/
*** kernel/cgroup.c
*** kernel/cgroup.c
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** inet_diag NETLINK socket addresses
** inet_diag NETLINK socket addresses
** ...
** ...
* chase down const-ification of function pointers (Kees Cook)
* chase down const-ification of function pointers
** Emese Revfy's patches
** Emese Revfy's patches
** Lionel Debroux's grsecurity extractions
** Lionel Debroux's grsecurity extractions

Latest revision as of 18:04, 15 November 2012

The Linux Security Workgroup has put together this page in an effort to bring the Linux security community together in hardening the Linux Kernel and to help prevent duplication of efforts. There are a number of desired Linux Kernel hardening projects listed below that are inactive and do not have an owner.

Process Improvements

Security Code Review Guidelines

This project is an effort to provide a reference that educates subsystem maintainers on what to look for when performing security reviews/audits. This would include various classes of common coding vulnerabilities and how to detect them, as well as other best practices, such as not leaving private keys laying around.

Patch Signing

This project would provide support to determine if patches have been modified or tampered since they were signed.

Verification of Critical Subsystems

This project would provide verification of critical subsystems such as:

  • Networking
  • Network file systems
  • KVM
  • Cryptographic library
  • Kernel build infrastructure

This could include approaches such as manual audits, static analysis, fuzz testing, etc.

Development

There are several kernel hardening features that have appeared in other hardened operating systems that would improve the security of Linux. Some have been controversial, so attempts have been made to describe them, including their controversy and discussion over the years, so as much information is available to make an educated decision about potential implementations.

Partial NX Emulation

Non-executable memory is likely one of the most important protections in modern computing. Hardware support exists for it in modern CPUs, but many systems do not benefit from this security.

To simulate the execute bit in the kernel's memory page tables, the CS register is used to break memory into two regions. This allows for a fast way to distinguish between memory above and below the CS-limit. Executable regions are loaded below the CS-limit. This is fast but not perfectly accurate, since the BSS regions of loaded libraries will remain in the executable region. It does provide a split between the loaded libraries (and BSS) and text segment from the brk and mmap heap and stack regions.

Versions of this patch have been carried by RedHat, SUSE, Openwall, grsecurity and others for a long time.

proposed upstream patch

chroot Protection

Many administrators attempt to contain potentially exploitable services in chroots. Unfortunately, chroots are not designed to be a security protection (they are for development and debugging). It is possible to reasonably contain a non-privileged process in a chroot, but attempting to contain a root user is fraught with pitfalls. While it is certainly possible to patch the kernel to have a hardened chroot() (for example, grsecurity has a large set of protections that lock down chroots) so many behaviors are changed and come in conflict with the more common development configurations.

Solutions are varied. Among the methods of chroot escape is manipulating the current working directory to be outside the current chroot via a second chroot() call (others include using /proc/*/cwd, fchdir(), and ptrace). This single flaw is trivial to fix, but does not block the other avenues, so the gain is very small when compared with the down-side of carrying a delta from the upstream kernel.

A better solution is to side-step the problem entirely. Since these security protections are being designed correctly with containers (see CLONE_NEW*), it would be better to use containers or MAC from the start when trying to isolate a service.

Some links to the history of its discussion:

Past objections and rebuttals could be summarized as:

  • Violates POSIX.
    • POSIX didn't consider or really define this situation, and it's not useful to follow a broken specification at the cost of security.
  • Might break debootstrap, debian-installer, and anything else that expects to chroot() within a chroot.
    • True, but maybe disallowing double-chroot is okay.
  • Can escape chroots in a large number of ways; containers are better.
    • Fix each flaw. Containers are not very easy to use yet.

Example implementation of cwd fix

Additional Kernel Hardening Development Projects

Following are more upstream Linux kernel projects that would make it harder for security vulnerabilities to become exploitable.

Note: Many CONFIG_* items below refer to PaX and grsecurity.

  • remove remaining kernel address leaks that prevent ASLR from being effective
    • https://patchwork.kernel.org/patch/487751/
      • kernel/cgroup.c
      • kernel/kprobes.c
      • kernel/lockdep_proc.c
    • /proc/mtrr
    • /proc/slabinfo
    • /proc/asound/cards
    • /sys/devices/*/*/resources
    • /proc/net/ptype
    • /sys/kernel/slab/*/ctor
    • /proc/iomem
    • inet_diag NETLINK socket addresses
    • ...
  • chase down const-ification of function pointers
  • examine page permissions and get rid of rwx mappings
  • implement __read_only for things that can't really be const, like CONFIG_PAX_KERNEXEC
  • disable set_kernel_text_rw() and friends via sysctl
  • module autoloading control, like CONFIG_GRKERNSEC_MODHARDEN
  • block hibernation image attacks (Vasiliy Kulikov)
  • copy_*_user() hardening, like CONFIG_PAX_USERCOPY
    • keep length under MAX_INT
    • validate targets against compiler knowledge of static buffers or look up buffer sizes from heap allocator
  • User/Kernel memory segmentation, like CONFIG_PAX_MEMORY_UDEREF or Intel SMEP
  • Kernel stack ASLR, like CONFIG_PAX_RANDKSTACK
  • Kernel stack clearing, like CONFIG_PAX_STACKLEAK
  • Kernel refcount overflow protection, like CONFIG_PAX_REFCOUNT
  • kernel symbol name hiding, like CONFIG_GRKERNSEC_HIDESYM
  • add -Wextra and perform associated cleanups
  • restricted access to vm86-related syscall/features, like CONFIG_HARDEN_VM86 in Linux 2.4.x-ow, but turned into a sysctl
  • ability to set/lock/force a process (and/or any children it might spawn) to 32-bit only or 64-bit only (or implement a general "personality lock" and have main/compat syscall availability be actually affected by the current personality, which is currently not the case)
    • this will be particularly useful with container-based virtualization (LXC, OpenVZ, vserver), where the container startup program will lock the bitness/personality before launching the container's /sbin/init (e.g., a prctl() affecting _only_ child processes - e.g., not yet vzctl, but the container's /sbin/init - will do for this purpose)
  • whitelist filesystem module autoloading. similar to rare network module blacklist

Userspace Protections