Linux 6.9-rc1

[linux-2.6-microblaze.git] / security / Kconfig.hardening

# SPDX-License-Identifier: GPL-2.0-only
menu "Kernel hardening options"

config GCC_PLUGIN_STRUCTLEAK
        bool
        help
          While the kernel is built with warnings enabled for any missed
          stack variable initializations, this warning is silenced for
          anything passed by reference to another function, under the
          occasionally misguided assumption that the function will do
          the initialization. As this regularly leads to exploitable
          flaws, this plugin is available to identify and zero-initialize
          such variables, depending on the chosen level of coverage.

          This plugin was originally ported from grsecurity/PaX. More
          information at:
           * https://grsecurity.net/
           * https://pax.grsecurity.net/

menu "Memory initialization"

config CC_HAS_AUTO_VAR_INIT_PATTERN
        def_bool $(cc-option,-ftrivial-auto-var-init=pattern)

config CC_HAS_AUTO_VAR_INIT_ZERO
        def_bool $(cc-option,-ftrivial-auto-var-init=zero -enable-trivial-auto-var-init-zero-knowing-it-will-be-removed-from-clang)

choice
        prompt "Initialize kernel stack variables at function entry"
        default GCC_PLUGIN_STRUCTLEAK_BYREF_ALL if COMPILE_TEST && GCC_PLUGINS
        default INIT_STACK_ALL_PATTERN if COMPILE_TEST && CC_HAS_AUTO_VAR_INIT_PATTERN
        default INIT_STACK_ALL_ZERO if CC_HAS_AUTO_VAR_INIT_PATTERN
        default INIT_STACK_NONE
        help
          This option enables initialization of stack variables at
          function entry time. This has the possibility to have the
          greatest coverage (since all functions can have their
          variables initialized), but the performance impact depends
          on the function calling complexity of a given workload's
          syscalls.

          This chooses the level of coverage over classes of potentially
          uninitialized variables. The selected class of variable will be
          initialized before use in a function.

        config INIT_STACK_NONE
                bool "no automatic stack variable initialization (weakest)"
                help
                  Disable automatic stack variable initialization.
                  This leaves the kernel vulnerable to the standard
                  classes of uninitialized stack variable exploits
                  and information exposures.

        config GCC_PLUGIN_STRUCTLEAK_USER
                bool "zero-init structs marked for userspace (weak)"
                depends on GCC_PLUGINS
                select GCC_PLUGIN_STRUCTLEAK
                help
                  Zero-initialize any structures on the stack containing
                  a __user attribute. This can prevent some classes of
                  uninitialized stack variable exploits and information
                  exposures, like CVE-2013-2141:
                  https://git.kernel.org/linus/b9e146d8eb3b9eca

        config GCC_PLUGIN_STRUCTLEAK_BYREF
                bool "zero-init structs passed by reference (strong)"
                depends on GCC_PLUGINS
                depends on !(KASAN && KASAN_STACK)
                select GCC_PLUGIN_STRUCTLEAK
                help
                  Zero-initialize any structures on the stack that may
                  be passed by reference and had not already been
                  explicitly initialized. This can prevent most classes
                  of uninitialized stack variable exploits and information
                  exposures, like CVE-2017-1000410:
                  https://git.kernel.org/linus/06e7e776ca4d3654

                  As a side-effect, this keeps a lot of variables on the
                  stack that can otherwise be optimized out, so combining
                  this with CONFIG_KASAN_STACK can lead to a stack overflow
                  and is disallowed.

        config GCC_PLUGIN_STRUCTLEAK_BYREF_ALL
                bool "zero-init everything passed by reference (very strong)"
                depends on GCC_PLUGINS
                depends on !(KASAN && KASAN_STACK)
                select GCC_PLUGIN_STRUCTLEAK
                help
                  Zero-initialize any stack variables that may be passed
                  by reference and had not already been explicitly
                  initialized. This is intended to eliminate all classes
                  of uninitialized stack variable exploits and information
                  exposures.

                  As a side-effect, this keeps a lot of variables on the
                  stack that can otherwise be optimized out, so combining
                  this with CONFIG_KASAN_STACK can lead to a stack overflow
                  and is disallowed.

        config INIT_STACK_ALL_PATTERN
                bool "pattern-init everything (strongest)"
                depends on CC_HAS_AUTO_VAR_INIT_PATTERN
                help
                  Initializes everything on the stack (including padding)
                  with a specific debug value. This is intended to eliminate
                  all classes of uninitialized stack variable exploits and
                  information exposures, even variables that were warned about
                  having been left uninitialized.

                  Pattern initialization is known to provoke many existing bugs
                  related to uninitialized locals, e.g. pointers receive
                  non-NULL values, buffer sizes and indices are very big. The
                  pattern is situation-specific; Clang on 64-bit uses 0xAA
                  repeating for all types and padding except float and double
                  which use 0xFF repeating (-NaN). Clang on 32-bit uses 0xFF
                  repeating for all types and padding.

        config INIT_STACK_ALL_ZERO
                bool "zero-init everything (strongest and safest)"
                depends on CC_HAS_AUTO_VAR_INIT_ZERO
                help
                  Initializes everything on the stack (including padding)
                  with a zero value. This is intended to eliminate all
                  classes of uninitialized stack variable exploits and
                  information exposures, even variables that were warned
                  about having been left uninitialized.

                  Zero initialization provides safe defaults for strings
                  (immediately NUL-terminated), pointers (NULL), indices
                  (index 0), and sizes (0 length), so it is therefore more
                  suitable as a production security mitigation than pattern
                  initialization.

endchoice

config GCC_PLUGIN_STRUCTLEAK_VERBOSE
        bool "Report forcefully initialized variables"
        depends on GCC_PLUGIN_STRUCTLEAK
        depends on !COMPILE_TEST        # too noisy
        help
          This option will cause a warning to be printed each time the
          structleak plugin finds a variable it thinks needs to be
          initialized. Since not all existing initializers are detected
          by the plugin, this can produce false positive warnings.

config GCC_PLUGIN_STACKLEAK
        bool "Poison kernel stack before returning from syscalls"
        depends on GCC_PLUGINS
        depends on HAVE_ARCH_STACKLEAK
        help
          This option makes the kernel erase the kernel stack before
          returning from system calls. This has the effect of leaving
          the stack initialized to the poison value, which both reduces
          the lifetime of any sensitive stack contents and reduces
          potential for uninitialized stack variable exploits or information
          exposures (it does not cover functions reaching the same stack
          depth as prior functions during the same syscall). This blocks
          most uninitialized stack variable attacks, with the performance
          impact being driven by the depth of the stack usage, rather than
          the function calling complexity.

          The performance impact on a single CPU system kernel compilation
          sees a 1% slowdown, other systems and workloads may vary and you
          are advised to test this feature on your expected workload before
          deploying it.

          This plugin was ported from grsecurity/PaX. More information at:
           * https://grsecurity.net/
           * https://pax.grsecurity.net/

config STACKLEAK_TRACK_MIN_SIZE
        int "Minimum stack frame size of functions tracked by STACKLEAK"
        default 100
        range 0 4096
        depends on GCC_PLUGIN_STACKLEAK
        help
          The STACKLEAK gcc plugin instruments the kernel code for tracking
          the lowest border of the kernel stack (and for some other purposes).
          It inserts the stackleak_track_stack() call for the functions with
          a stack frame size greater than or equal to this parameter.
          If unsure, leave the default value 100.

config STACKLEAK_METRICS
        bool "Show STACKLEAK metrics in the /proc file system"
        depends on GCC_PLUGIN_STACKLEAK
        depends on PROC_FS
        help
          If this is set, STACKLEAK metrics for every task are available in
          the /proc file system. In particular, /proc/<pid>/stack_depth
          shows the maximum kernel stack consumption for the current and
          previous syscalls. Although this information is not precise, it
          can be useful for estimating the STACKLEAK performance impact for
          your workloads.

config STACKLEAK_RUNTIME_DISABLE
        bool "Allow runtime disabling of kernel stack erasing"
        depends on GCC_PLUGIN_STACKLEAK
        help
          This option provides 'stack_erasing' sysctl, which can be used in
          runtime to control kernel stack erasing for kernels built with
          CONFIG_GCC_PLUGIN_STACKLEAK.

config INIT_ON_ALLOC_DEFAULT_ON
        bool "Enable heap memory zeroing on allocation by default"
        help
          This has the effect of setting "init_on_alloc=1" on the kernel
          command line. This can be disabled with "init_on_alloc=0".
          When "init_on_alloc" is enabled, all page allocator and slab
          allocator memory will be zeroed when allocated, eliminating
          many kinds of "uninitialized heap memory" flaws, especially
          heap content exposures. The performance impact varies by
          workload, but most cases see <1% impact. Some synthetic
          workloads have measured as high as 7%.

config INIT_ON_FREE_DEFAULT_ON
        bool "Enable heap memory zeroing on free by default"
        help
          This has the effect of setting "init_on_free=1" on the kernel
          command line. This can be disabled with "init_on_free=0".
          Similar to "init_on_alloc", when "init_on_free" is enabled,
          all page allocator and slab allocator memory will be zeroed
          when freed, eliminating many kinds of "uninitialized heap memory"
          flaws, especially heap content exposures. The primary difference
          with "init_on_free" is that data lifetime in memory is reduced,
          as anything freed is wiped immediately, making live forensics or
          cold boot memory attacks unable to recover freed memory contents.
          The performance impact varies by workload, but is more expensive
          than "init_on_alloc" due to the negative cache effects of
          touching "cold" memory areas. Most cases see 3-5% impact. Some
          synthetic workloads have measured as high as 8%.

config CC_HAS_ZERO_CALL_USED_REGS
        def_bool $(cc-option,-fzero-call-used-regs=used-gpr)

config ZERO_CALL_USED_REGS
        bool "Enable register zeroing on function exit"
        depends on CC_HAS_ZERO_CALL_USED_REGS
        help
          At the end of functions, always zero any caller-used register
          contents. This helps ensure that temporary values are not
          leaked beyond the function boundary. This means that register
          contents are less likely to be available for side channels
          and information exposures. Additionally, this helps reduce the
          number of useful ROP gadgets by about 20% (and removes compiler
          generated "write-what-where" gadgets) in the resulting kernel
          image. This has a less than 1% performance impact on most
          workloads. Image size growth depends on architecture, and should
          be evaluated for suitability. For example, x86_64 grows by less
          than 1%, and arm64 grows by about 5%.

endmenu

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