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050e9baa9d
The changes to automatically test for working stack protector compiler support in the Kconfig files removed the special STACKPROTECTOR_AUTO option that picked the strongest stack protector that the compiler supported. That was all a nice cleanup - it makes no sense to have the AUTO case now that the Kconfig phase can just determine the compiler support directly. HOWEVER. It also meant that doing "make oldconfig" would now _disable_ the strong stackprotector if you had AUTO enabled, because in a legacy config file, the sane stack protector configuration would look like CONFIG_HAVE_CC_STACKPROTECTOR=y # CONFIG_CC_STACKPROTECTOR_NONE is not set # CONFIG_CC_STACKPROTECTOR_REGULAR is not set # CONFIG_CC_STACKPROTECTOR_STRONG is not set CONFIG_CC_STACKPROTECTOR_AUTO=y and when you ran this through "make oldconfig" with the Kbuild changes, it would ask you about the regular CONFIG_CC_STACKPROTECTOR (that had been renamed from CONFIG_CC_STACKPROTECTOR_REGULAR to just CONFIG_CC_STACKPROTECTOR), but it would think that the STRONG version used to be disabled (because it was really enabled by AUTO), and would disable it in the new config, resulting in: CONFIG_HAVE_CC_STACKPROTECTOR=y CONFIG_CC_HAS_STACKPROTECTOR_NONE=y CONFIG_CC_STACKPROTECTOR=y # CONFIG_CC_STACKPROTECTOR_STRONG is not set CONFIG_CC_HAS_SANE_STACKPROTECTOR=y That's dangerously subtle - people could suddenly find themselves with the weaker stack protector setup without even realizing. The solution here is to just rename not just the old RECULAR stack protector option, but also the strong one. This does that by just removing the CC_ prefix entirely for the user choices, because it really is not about the compiler support (the compiler support now instead automatially impacts _visibility_ of the options to users). This results in "make oldconfig" actually asking the user for their choice, so that we don't have any silent subtle security model changes. The end result would generally look like this: CONFIG_HAVE_CC_STACKPROTECTOR=y CONFIG_CC_HAS_STACKPROTECTOR_NONE=y CONFIG_STACKPROTECTOR=y CONFIG_STACKPROTECTOR_STRONG=y CONFIG_CC_HAS_SANE_STACKPROTECTOR=y where the "CC_" versions really are about internal compiler infrastructure, not the user selections. Acked-by: Masahiro Yamada <yamada.masahiro@socionext.com> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
318 lines
13 KiB
ReStructuredText
318 lines
13 KiB
ReStructuredText
======================
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Kernel Self-Protection
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======================
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Kernel self-protection is the design and implementation of systems and
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structures within the Linux kernel to protect against security flaws in
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the kernel itself. This covers a wide range of issues, including removing
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entire classes of bugs, blocking security flaw exploitation methods,
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and actively detecting attack attempts. Not all topics are explored in
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this document, but it should serve as a reasonable starting point and
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answer any frequently asked questions. (Patches welcome, of course!)
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In the worst-case scenario, we assume an unprivileged local attacker
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has arbitrary read and write access to the kernel's memory. In many
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cases, bugs being exploited will not provide this level of access,
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but with systems in place that defend against the worst case we'll
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cover the more limited cases as well. A higher bar, and one that should
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still be kept in mind, is protecting the kernel against a _privileged_
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local attacker, since the root user has access to a vastly increased
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attack surface. (Especially when they have the ability to load arbitrary
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kernel modules.)
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The goals for successful self-protection systems would be that they
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are effective, on by default, require no opt-in by developers, have no
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performance impact, do not impede kernel debugging, and have tests. It
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is uncommon that all these goals can be met, but it is worth explicitly
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mentioning them, since these aspects need to be explored, dealt with,
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and/or accepted.
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Attack Surface Reduction
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========================
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The most fundamental defense against security exploits is to reduce the
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areas of the kernel that can be used to redirect execution. This ranges
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from limiting the exposed APIs available to userspace, making in-kernel
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APIs hard to use incorrectly, minimizing the areas of writable kernel
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memory, etc.
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Strict kernel memory permissions
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--------------------------------
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When all of kernel memory is writable, it becomes trivial for attacks
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to redirect execution flow. To reduce the availability of these targets
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the kernel needs to protect its memory with a tight set of permissions.
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Executable code and read-only data must not be writable
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Any areas of the kernel with executable memory must not be writable.
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While this obviously includes the kernel text itself, we must consider
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all additional places too: kernel modules, JIT memory, etc. (There are
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temporary exceptions to this rule to support things like instruction
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alternatives, breakpoints, kprobes, etc. If these must exist in a
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kernel, they are implemented in a way where the memory is temporarily
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made writable during the update, and then returned to the original
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permissions.)
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In support of this are ``CONFIG_STRICT_KERNEL_RWX`` and
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``CONFIG_STRICT_MODULE_RWX``, which seek to make sure that code is not
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writable, data is not executable, and read-only data is neither writable
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nor executable.
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Most architectures have these options on by default and not user selectable.
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For some architectures like arm that wish to have these be selectable,
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the architecture Kconfig can select ARCH_OPTIONAL_KERNEL_RWX to enable
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a Kconfig prompt. ``CONFIG_ARCH_OPTIONAL_KERNEL_RWX_DEFAULT`` determines
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the default setting when ARCH_OPTIONAL_KERNEL_RWX is enabled.
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Function pointers and sensitive variables must not be writable
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Vast areas of kernel memory contain function pointers that are looked
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up by the kernel and used to continue execution (e.g. descriptor/vector
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tables, file/network/etc operation structures, etc). The number of these
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variables must be reduced to an absolute minimum.
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Many such variables can be made read-only by setting them "const"
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so that they live in the .rodata section instead of the .data section
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of the kernel, gaining the protection of the kernel's strict memory
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permissions as described above.
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For variables that are initialized once at ``__init`` time, these can
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be marked with the (new and under development) ``__ro_after_init``
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attribute.
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What remains are variables that are updated rarely (e.g. GDT). These
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will need another infrastructure (similar to the temporary exceptions
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made to kernel code mentioned above) that allow them to spend the rest
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of their lifetime read-only. (For example, when being updated, only the
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CPU thread performing the update would be given uninterruptible write
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access to the memory.)
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Segregation of kernel memory from userspace memory
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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The kernel must never execute userspace memory. The kernel must also never
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access userspace memory without explicit expectation to do so. These
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rules can be enforced either by support of hardware-based restrictions
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(x86's SMEP/SMAP, ARM's PXN/PAN) or via emulation (ARM's Memory Domains).
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By blocking userspace memory in this way, execution and data parsing
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cannot be passed to trivially-controlled userspace memory, forcing
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attacks to operate entirely in kernel memory.
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Reduced access to syscalls
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--------------------------
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One trivial way to eliminate many syscalls for 64-bit systems is building
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without ``CONFIG_COMPAT``. However, this is rarely a feasible scenario.
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The "seccomp" system provides an opt-in feature made available to
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userspace, which provides a way to reduce the number of kernel entry
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points available to a running process. This limits the breadth of kernel
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code that can be reached, possibly reducing the availability of a given
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bug to an attack.
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An area of improvement would be creating viable ways to keep access to
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things like compat, user namespaces, BPF creation, and perf limited only
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to trusted processes. This would keep the scope of kernel entry points
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restricted to the more regular set of normally available to unprivileged
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userspace.
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Restricting access to kernel modules
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------------------------------------
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The kernel should never allow an unprivileged user the ability to
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load specific kernel modules, since that would provide a facility to
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unexpectedly extend the available attack surface. (The on-demand loading
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of modules via their predefined subsystems, e.g. MODULE_ALIAS_*, is
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considered "expected" here, though additional consideration should be
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given even to these.) For example, loading a filesystem module via an
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unprivileged socket API is nonsense: only the root or physically local
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user should trigger filesystem module loading. (And even this can be up
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for debate in some scenarios.)
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To protect against even privileged users, systems may need to either
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disable module loading entirely (e.g. monolithic kernel builds or
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modules_disabled sysctl), or provide signed modules (e.g.
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``CONFIG_MODULE_SIG_FORCE``, or dm-crypt with LoadPin), to keep from having
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root load arbitrary kernel code via the module loader interface.
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Memory integrity
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================
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There are many memory structures in the kernel that are regularly abused
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to gain execution control during an attack, By far the most commonly
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understood is that of the stack buffer overflow in which the return
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address stored on the stack is overwritten. Many other examples of this
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kind of attack exist, and protections exist to defend against them.
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Stack buffer overflow
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---------------------
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The classic stack buffer overflow involves writing past the expected end
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of a variable stored on the stack, ultimately writing a controlled value
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to the stack frame's stored return address. The most widely used defense
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is the presence of a stack canary between the stack variables and the
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return address (``CONFIG_STACKPROTECTOR``), which is verified just before
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the function returns. Other defenses include things like shadow stacks.
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Stack depth overflow
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--------------------
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A less well understood attack is using a bug that triggers the
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kernel to consume stack memory with deep function calls or large stack
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allocations. With this attack it is possible to write beyond the end of
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the kernel's preallocated stack space and into sensitive structures. Two
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important changes need to be made for better protections: moving the
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sensitive thread_info structure elsewhere, and adding a faulting memory
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hole at the bottom of the stack to catch these overflows.
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Heap memory integrity
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---------------------
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The structures used to track heap free lists can be sanity-checked during
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allocation and freeing to make sure they aren't being used to manipulate
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other memory areas.
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Counter integrity
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-----------------
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Many places in the kernel use atomic counters to track object references
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or perform similar lifetime management. When these counters can be made
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to wrap (over or under) this traditionally exposes a use-after-free
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flaw. By trapping atomic wrapping, this class of bug vanishes.
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Size calculation overflow detection
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-----------------------------------
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Similar to counter overflow, integer overflows (usually size calculations)
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need to be detected at runtime to kill this class of bug, which
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traditionally leads to being able to write past the end of kernel buffers.
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Probabilistic defenses
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======================
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While many protections can be considered deterministic (e.g. read-only
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memory cannot be written to), some protections provide only statistical
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defense, in that an attack must gather enough information about a
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running system to overcome the defense. While not perfect, these do
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provide meaningful defenses.
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Canaries, blinding, and other secrets
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-------------------------------------
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It should be noted that things like the stack canary discussed earlier
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are technically statistical defenses, since they rely on a secret value,
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and such values may become discoverable through an information exposure
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flaw.
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Blinding literal values for things like JITs, where the executable
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contents may be partially under the control of userspace, need a similar
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secret value.
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It is critical that the secret values used must be separate (e.g.
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different canary per stack) and high entropy (e.g. is the RNG actually
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working?) in order to maximize their success.
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Kernel Address Space Layout Randomization (KASLR)
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-------------------------------------------------
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Since the location of kernel memory is almost always instrumental in
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mounting a successful attack, making the location non-deterministic
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raises the difficulty of an exploit. (Note that this in turn makes
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the value of information exposures higher, since they may be used to
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discover desired memory locations.)
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Text and module base
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~~~~~~~~~~~~~~~~~~~~
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By relocating the physical and virtual base address of the kernel at
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boot-time (``CONFIG_RANDOMIZE_BASE``), attacks needing kernel code will be
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frustrated. Additionally, offsetting the module loading base address
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means that even systems that load the same set of modules in the same
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order every boot will not share a common base address with the rest of
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the kernel text.
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Stack base
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~~~~~~~~~~
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If the base address of the kernel stack is not the same between processes,
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or even not the same between syscalls, targets on or beyond the stack
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become more difficult to locate.
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Dynamic memory base
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~~~~~~~~~~~~~~~~~~~
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Much of the kernel's dynamic memory (e.g. kmalloc, vmalloc, etc) ends up
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being relatively deterministic in layout due to the order of early-boot
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initializations. If the base address of these areas is not the same
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between boots, targeting them is frustrated, requiring an information
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exposure specific to the region.
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Structure layout
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~~~~~~~~~~~~~~~~
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By performing a per-build randomization of the layout of sensitive
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structures, attacks must either be tuned to known kernel builds or expose
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enough kernel memory to determine structure layouts before manipulating
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them.
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Preventing Information Exposures
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================================
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Since the locations of sensitive structures are the primary target for
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attacks, it is important to defend against exposure of both kernel memory
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addresses and kernel memory contents (since they may contain kernel
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addresses or other sensitive things like canary values).
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Kernel addresses
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----------------
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Printing kernel addresses to userspace leaks sensitive information about
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the kernel memory layout. Care should be exercised when using any printk
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specifier that prints the raw address, currently %px, %p[ad], (and %p[sSb]
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in certain circumstances [*]). Any file written to using one of these
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specifiers should be readable only by privileged processes.
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Kernels 4.14 and older printed the raw address using %p. As of 4.15-rc1
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addresses printed with the specifier %p are hashed before printing.
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[*] If KALLSYMS is enabled and symbol lookup fails, the raw address is
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printed. If KALLSYMS is not enabled the raw address is printed.
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Unique identifiers
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------------------
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Kernel memory addresses must never be used as identifiers exposed to
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userspace. Instead, use an atomic counter, an idr, or similar unique
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identifier.
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Memory initialization
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---------------------
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Memory copied to userspace must always be fully initialized. If not
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explicitly memset(), this will require changes to the compiler to make
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sure structure holes are cleared.
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Memory poisoning
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----------------
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When releasing memory, it is best to poison the contents (clear stack on
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syscall return, wipe heap memory on a free), to avoid reuse attacks that
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rely on the old contents of memory. This frustrates many uninitialized
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variable attacks, stack content exposures, heap content exposures, and
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use-after-free attacks.
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Destination tracking
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--------------------
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To help kill classes of bugs that result in kernel addresses being
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written to userspace, the destination of writes needs to be tracked. If
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the buffer is destined for userspace (e.g. seq_file backed ``/proc`` files),
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it should automatically censor sensitive values.
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