Documentation/dev-tools/kfence.rst - linux - Git at Google

 .. SPDX-License-Identifier: GPL-2.0
 .. Copyright (C) 2020, Google LLC.

 Kernel Electric-Fence (KFENCE)
 ==============================

 Kernel Electric-Fence (KFENCE) is a low-overhead sampling-based memory safety
 error detector. KFENCE detects heap out-of-bounds access, use-after-free, and
 invalid-free errors.

 KFENCE is designed to be enabled in production kernels, and has near zero
 performance overhead. Compared to KASAN, KFENCE trades performance for
 precision. The main motivation behind KFENCE's design, is that with enough
 total uptime KFENCE will detect bugs in code paths not typically exercised by
 non-production test workloads. One way to quickly achieve a large enough total
 uptime is when the tool is deployed across a large fleet of machines.

 Usage
 -----

 To enable KFENCE, configure the kernel with::

     CONFIG_KFENCE=y

 To build a kernel with KFENCE support, but disabled by default (to enable, set
 ``kfence.sample_interval`` to non-zero value), configure the kernel with::

     CONFIG_KFENCE=y
     CONFIG_KFENCE_SAMPLE_INTERVAL=0

 KFENCE provides several other configuration options to customize behaviour (see
 the respective help text in ``lib/Kconfig.kfence`` for more info).

 Tuning performance
 ~~~~~~~~~~~~~~~~~~

 The most important parameter is KFENCE's sample interval, which can be set via
 the kernel boot parameter ``kfence.sample_interval`` in milliseconds. The
 sample interval determines the frequency with which heap allocations will be
 guarded by KFENCE. The default is configurable via the Kconfig option
 ``CONFIG_KFENCE_SAMPLE_INTERVAL``. Setting ``kfence.sample_interval=0``
 disables KFENCE.

 The sample interval controls a timer that sets up KFENCE allocations. By
 default, to keep the real sample interval predictable, the normal timer also
 causes CPU wake-ups when the system is completely idle. This may be undesirable
 on power-constrained systems. The boot parameter ``kfence.deferrable=1``
 instead switches to a "deferrable" timer which does not force CPU wake-ups on
 idle systems, at the risk of unpredictable sample intervals. The default is
 configurable via the Kconfig option ``CONFIG_KFENCE_DEFERRABLE``.

 .. warning::
    The KUnit test suite is very likely to fail when using a deferrable timer
    since it currently causes very unpredictable sample intervals.

 The KFENCE memory pool is of fixed size, and if the pool is exhausted, no
 further KFENCE allocations occur. With ``CONFIG_KFENCE_NUM_OBJECTS`` (default
 255), the number of available guarded objects can be controlled. Each object
 requires 2 pages, one for the object itself and the other one used as a guard
 page; object pages are interleaved with guard pages, and every object page is
 therefore surrounded by two guard pages.

 The total memory dedicated to the KFENCE memory pool can be computed as::

     ( #objects + 1 ) * 2 * PAGE_SIZE

 Using the default config, and assuming a page size of 4 KiB, results in
 dedicating 2 MiB to the KFENCE memory pool.

 Note: On architectures that support huge pages, KFENCE will ensure that the
 pool is using pages of size ``PAGE_SIZE``. This will result in additional page
 tables being allocated.

 Error reports
 ~~~~~~~~~~~~~

 A typical out-of-bounds access looks like this::

     ==================================================================
     BUG: KFENCE: out-of-bounds read in test_out_of_bounds_read+0xa6/0x234

     Out-of-bounds read at 0xffff8c3f2e291fff (1B left of kfence-#72):
      test_out_of_bounds_read+0xa6/0x234
      kunit_try_run_case+0x61/0xa0
      kunit_generic_run_threadfn_adapter+0x16/0x30
      kthread+0x176/0x1b0
      ret_from_fork+0x22/0x30

     kfence-#72: 0xffff8c3f2e292000-0xffff8c3f2e29201f, size=32, cache=kmalloc-32

     allocated by task 484 on cpu 0 at 32.919330s:
      test_alloc+0xfe/0x738
      test_out_of_bounds_read+0x9b/0x234
      kunit_try_run_case+0x61/0xa0
      kunit_generic_run_threadfn_adapter+0x16/0x30
      kthread+0x176/0x1b0
      ret_from_fork+0x22/0x30

     CPU: 0 PID: 484 Comm: kunit_try_catch Not tainted 5.13.0-rc3+ #7
     Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.14.0-2 04/01/2014
     ==================================================================

 The header of the report provides a short summary of the function involved in
 the access. It is followed by more detailed information about the access and
 its origin. Note that, real kernel addresses are only shown when using the
 kernel command line option ``no_hash_pointers``.

 Use-after-free accesses are reported as::

     ==================================================================
     BUG: KFENCE: use-after-free read in test_use_after_free_read+0xb3/0x143

     Use-after-free read at 0xffff8c3f2e2a0000 (in kfence-#79):
      test_use_after_free_read+0xb3/0x143
      kunit_try_run_case+0x61/0xa0
      kunit_generic_run_threadfn_adapter+0x16/0x30
      kthread+0x176/0x1b0
      ret_from_fork+0x22/0x30

     kfence-#79: 0xffff8c3f2e2a0000-0xffff8c3f2e2a001f, size=32, cache=kmalloc-32

     allocated by task 488 on cpu 2 at 33.871326s:
      test_alloc+0xfe/0x738
      test_use_after_free_read+0x76/0x143
      kunit_try_run_case+0x61/0xa0
      kunit_generic_run_threadfn_adapter+0x16/0x30
      kthread+0x176/0x1b0
      ret_from_fork+0x22/0x30

     freed by task 488 on cpu 2 at 33.871358s:
      test_use_after_free_read+0xa8/0x143
      kunit_try_run_case+0x61/0xa0
      kunit_generic_run_threadfn_adapter+0x16/0x30
      kthread+0x176/0x1b0
      ret_from_fork+0x22/0x30

     CPU: 2 PID: 488 Comm: kunit_try_catch Tainted: G    B             5.13.0-rc3+ #7
     Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.14.0-2 04/01/2014
     ==================================================================

 KFENCE also reports on invalid frees, such as double-frees::

     ==================================================================
     BUG: KFENCE: invalid free in test_double_free+0xdc/0x171

     Invalid free of 0xffff8c3f2e2a4000 (in kfence-#81):
      test_double_free+0xdc/0x171
      kunit_try_run_case+0x61/0xa0
      kunit_generic_run_threadfn_adapter+0x16/0x30
      kthread+0x176/0x1b0
      ret_from_fork+0x22/0x30

     kfence-#81: 0xffff8c3f2e2a4000-0xffff8c3f2e2a401f, size=32, cache=kmalloc-32

     allocated by task 490 on cpu 1 at 34.175321s:
      test_alloc+0xfe/0x738
      test_double_free+0x76/0x171
      kunit_try_run_case+0x61/0xa0
      kunit_generic_run_threadfn_adapter+0x16/0x30
      kthread+0x176/0x1b0
      ret_from_fork+0x22/0x30

     freed by task 490 on cpu 1 at 34.175348s:
      test_double_free+0xa8/0x171
      kunit_try_run_case+0x61/0xa0
      kunit_generic_run_threadfn_adapter+0x16/0x30
      kthread+0x176/0x1b0
      ret_from_fork+0x22/0x30

     CPU: 1 PID: 490 Comm: kunit_try_catch Tainted: G    B             5.13.0-rc3+ #7
     Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.14.0-2 04/01/2014
     ==================================================================

 KFENCE also uses pattern-based redzones on the other side of an object's guard
 page, to detect out-of-bounds writes on the unprotected side of the object.
 These are reported on frees::

     ==================================================================
     BUG: KFENCE: memory corruption in test_kmalloc_aligned_oob_write+0xef/0x184

     Corrupted memory at 0xffff8c3f2e33aff9 [ 0xac . . . . . . ] (in kfence-#156):
      test_kmalloc_aligned_oob_write+0xef/0x184
      kunit_try_run_case+0x61/0xa0
      kunit_generic_run_threadfn_adapter+0x16/0x30
      kthread+0x176/0x1b0
      ret_from_fork+0x22/0x30

     kfence-#156: 0xffff8c3f2e33afb0-0xffff8c3f2e33aff8, size=73, cache=kmalloc-96

     allocated by task 502 on cpu 7 at 42.159302s:
      test_alloc+0xfe/0x738
      test_kmalloc_aligned_oob_write+0x57/0x184
      kunit_try_run_case+0x61/0xa0
      kunit_generic_run_threadfn_adapter+0x16/0x30
      kthread+0x176/0x1b0
      ret_from_fork+0x22/0x30

     CPU: 7 PID: 502 Comm: kunit_try_catch Tainted: G    B             5.13.0-rc3+ #7
     Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.14.0-2 04/01/2014
     ==================================================================

 For such errors, the address where the corruption occurred as well as the
 invalidly written bytes (offset from the address) are shown; in this
 representation, '.' denote untouched bytes. In the example above ``0xac`` is
 the value written to the invalid address at offset 0, and the remaining '.'
 denote that no following bytes have been touched. Note that, real values are
 only shown if the kernel was booted with ``no_hash_pointers``; to avoid
 information disclosure otherwise, '!' is used instead to denote invalidly
 written bytes.

 And finally, KFENCE may also report on invalid accesses to any protected page
 where it was not possible to determine an associated object, e.g. if adjacent
 object pages had not yet been allocated::

     ==================================================================
     BUG: KFENCE: invalid read in test_invalid_access+0x26/0xe0

     Invalid read at 0xffffffffb670b00a:
      test_invalid_access+0x26/0xe0
      kunit_try_run_case+0x51/0x85
      kunit_generic_run_threadfn_adapter+0x16/0x30
      kthread+0x137/0x160
      ret_from_fork+0x22/0x30

     CPU: 4 PID: 124 Comm: kunit_try_catch Tainted: G        W         5.8.0-rc6+ #7
     Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.13.0-1 04/01/2014
     ==================================================================

 DebugFS interface
 ~~~~~~~~~~~~~~~~~

 Some debugging information is exposed via debugfs:

 * The file ``/sys/kernel/debug/kfence/stats`` provides runtime statistics.

 * The file ``/sys/kernel/debug/kfence/objects`` provides a list of objects
   allocated via KFENCE, including those already freed but protected.

 Implementation Details
 ----------------------

 Guarded allocations are set up based on the sample interval. After expiration
 of the sample interval, the next allocation through the main allocator (SLAB or
 SLUB) returns a guarded allocation from the KFENCE object pool (allocation
 sizes up to PAGE_SIZE are supported). At this point, the timer is reset, and
 the next allocation is set up after the expiration of the interval.

 When using ``CONFIG_KFENCE_STATIC_KEYS=y``, KFENCE allocations are "gated"
 through the main allocator's fast-path by relying on static branches via the
 static keys infrastructure. The static branch is toggled to redirect the
 allocation to KFENCE. Depending on sample interval, target workloads, and
 system architecture, this may perform better than the simple dynamic branch.
 Careful benchmarking is recommended.

 KFENCE objects each reside on a dedicated page, at either the left or right
 page boundaries selected at random. The pages to the left and right of the
 object page are "guard pages", whose attributes are changed to a protected
 state, and cause page faults on any attempted access. Such page faults are then
 intercepted by KFENCE, which handles the fault gracefully by reporting an
 out-of-bounds access, and marking the page as accessible so that the faulting
 code can (wrongly) continue executing (set ``panic_on_warn`` to panic instead).

 To detect out-of-bounds writes to memory within the object's page itself,
 KFENCE also uses pattern-based redzones. For each object page, a redzone is set
 up for all non-object memory. For typical alignments, the redzone is only
 required on the unguarded side of an object. Because KFENCE must honor the
 cache's requested alignment, special alignments may result in unprotected gaps
 on either side of an object, all of which are redzoned.

 The following figure illustrates the page layout::

     ---+-----------+-----------+-----------+-----------+-----------+---
        | xxxxxxxxx | O :       | xxxxxxxxx |       : O | xxxxxxxxx |
        | xxxxxxxxx | B :       | xxxxxxxxx |       : B | xxxxxxxxx |
        | x GUARD x | J : RED-  | x GUARD x | RED-  : J | x GUARD x |
        | xxxxxxxxx | E :  ZONE | xxxxxxxxx |  ZONE : E | xxxxxxxxx |
        | xxxxxxxxx | C :       | xxxxxxxxx |       : C | xxxxxxxxx |
        | xxxxxxxxx | T :       | xxxxxxxxx |       : T | xxxxxxxxx |
     ---+-----------+-----------+-----------+-----------+-----------+---

 Upon deallocation of a KFENCE object, the object's page is again protected and
 the object is marked as freed. Any further access to the object causes a fault
 and KFENCE reports a use-after-free access. Freed objects are inserted at the
 tail of KFENCE's freelist, so that the least recently freed objects are reused
 first, and the chances of detecting use-after-frees of recently freed objects
 is increased.

 If pool utilization reaches 75% (default) or above, to reduce the risk of the
 pool eventually being fully occupied by allocated objects yet ensure diverse
 coverage of allocations, KFENCE limits currently covered allocations of the
 same source from further filling up the pool. The "source" of an allocation is
 based on its partial allocation stack trace. A side-effect is that this also
 limits frequent long-lived allocations (e.g. pagecache) of the same source
 filling up the pool permanently, which is the most common risk for the pool
 becoming full and the sampled allocation rate dropping to zero. The threshold
 at which to start limiting currently covered allocations can be configured via
 the boot parameter ``kfence.skip_covered_thresh`` (pool usage%).

 Interface
 ---------

 The following describes the functions which are used by allocators as well as
 page handling code to set up and deal with KFENCE allocations.

 .. kernel-doc:: include/linux/kfence.h
    :functions: is_kfence_address
                kfence_shutdown_cache
                kfence_alloc kfence_free __kfence_free
                kfence_ksize kfence_object_start
                kfence_handle_page_fault

 Related Tools
 -------------

 In userspace, a similar approach is taken by `GWP-ASan
 <http://llvm.org/docs/GwpAsan.html>`_. GWP-ASan also relies on guard pages and
 a sampling strategy to detect memory unsafety bugs at scale. KFENCE's design is
 directly influenced by GWP-ASan, and can be seen as its kernel sibling. Another
 similar but non-sampling approach, that also inspired the name "KFENCE", can be
 found in the userspace `Electric Fence Malloc Debugger
 <https://linux.die.net/man/3/efence>`_.

 In the kernel, several tools exist to debug memory access errors, and in
 particular KASAN can detect all bug classes that KFENCE can detect. While KASAN
 is more precise, relying on compiler instrumentation, this comes at a
 performance cost.

 It is worth highlighting that KASAN and KFENCE are complementary, with
 different target environments. For instance, KASAN is the better debugging-aid,
 where test cases or reproducers exists: due to the lower chance to detect the
 error, it would require more effort using KFENCE to debug. Deployments at scale
 that cannot afford to enable KASAN, however, would benefit from using KFENCE to
 discover bugs due to code paths not exercised by test cases or fuzzers.
	.. SPDX-License-Identifier: GPL-2.0
	.. Copyright (C) 2020, Google LLC.

	Kernel Electric-Fence (KFENCE)
	==============================

	Kernel Electric-Fence (KFENCE) is a low-overhead sampling-based memory safety
	error detector. KFENCE detects heap out-of-bounds access, use-after-free, and
	invalid-free errors.

	KFENCE is designed to be enabled in production kernels, and has near zero
	performance overhead. Compared to KASAN, KFENCE trades performance for
	precision. The main motivation behind KFENCE's design, is that with enough
	total uptime KFENCE will detect bugs in code paths not typically exercised by
	non-production test workloads. One way to quickly achieve a large enough total
	uptime is when the tool is deployed across a large fleet of machines.

	Usage
	-----

	To enable KFENCE, configure the kernel with::

	CONFIG_KFENCE=y

	To build a kernel with KFENCE support, but disabled by default (to enable, set
	``kfence.sample_interval`` to non-zero value), configure the kernel with::

	CONFIG_KFENCE=y
	CONFIG_KFENCE_SAMPLE_INTERVAL=0

	KFENCE provides several other configuration options to customize behaviour (see
	the respective help text in ``lib/Kconfig.kfence`` for more info).

	Tuning performance
	~~~~~~~~~~~~~~~~~~

	The most important parameter is KFENCE's sample interval, which can be set via
	the kernel boot parameter ``kfence.sample_interval`` in milliseconds. The
	sample interval determines the frequency with which heap allocations will be
	guarded by KFENCE. The default is configurable via the Kconfig option
	``CONFIG_KFENCE_SAMPLE_INTERVAL``. Setting ``kfence.sample_interval=0``
	disables KFENCE.

	The sample interval controls a timer that sets up KFENCE allocations. By
	default, to keep the real sample interval predictable, the normal timer also
	causes CPU wake-ups when the system is completely idle. This may be undesirable
	on power-constrained systems. The boot parameter ``kfence.deferrable=1``
	instead switches to a "deferrable" timer which does not force CPU wake-ups on
	idle systems, at the risk of unpredictable sample intervals. The default is
	configurable via the Kconfig option ``CONFIG_KFENCE_DEFERRABLE``.

	.. warning::
	The KUnit test suite is very likely to fail when using a deferrable timer
	since it currently causes very unpredictable sample intervals.

	The KFENCE memory pool is of fixed size, and if the pool is exhausted, no
	further KFENCE allocations occur. With ``CONFIG_KFENCE_NUM_OBJECTS`` (default
	255), the number of available guarded objects can be controlled. Each object
	requires 2 pages, one for the object itself and the other one used as a guard
	page; object pages are interleaved with guard pages, and every object page is
	therefore surrounded by two guard pages.

	The total memory dedicated to the KFENCE memory pool can be computed as::

	( #objects + 1 ) * 2 * PAGE_SIZE

	Using the default config, and assuming a page size of 4 KiB, results in
	dedicating 2 MiB to the KFENCE memory pool.

	Note: On architectures that support huge pages, KFENCE will ensure that the
	pool is using pages of size ``PAGE_SIZE``. This will result in additional page
	tables being allocated.

	Error reports
	~~~~~~~~~~~~~

	A typical out-of-bounds access looks like this::

	==================================================================
	BUG: KFENCE: out-of-bounds read in test_out_of_bounds_read+0xa6/0x234

	Out-of-bounds read at 0xffff8c3f2e291fff (1B left of kfence-#72):
	test_out_of_bounds_read+0xa6/0x234
	kunit_try_run_case+0x61/0xa0
	kunit_generic_run_threadfn_adapter+0x16/0x30
	kthread+0x176/0x1b0
	ret_from_fork+0x22/0x30

	kfence-#72: 0xffff8c3f2e292000-0xffff8c3f2e29201f, size=32, cache=kmalloc-32

	allocated by task 484 on cpu 0 at 32.919330s:
	test_alloc+0xfe/0x738
	test_out_of_bounds_read+0x9b/0x234
	kunit_try_run_case+0x61/0xa0
	kunit_generic_run_threadfn_adapter+0x16/0x30
	kthread+0x176/0x1b0
	ret_from_fork+0x22/0x30

	CPU: 0 PID: 484 Comm: kunit_try_catch Not tainted 5.13.0-rc3+ #7
	Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.14.0-2 04/01/2014
	==================================================================

	The header of the report provides a short summary of the function involved in
	the access. It is followed by more detailed information about the access and
	its origin. Note that, real kernel addresses are only shown when using the
	kernel command line option ``no_hash_pointers``.

	Use-after-free accesses are reported as::

	==================================================================
	BUG: KFENCE: use-after-free read in test_use_after_free_read+0xb3/0x143

	Use-after-free read at 0xffff8c3f2e2a0000 (in kfence-#79):
	test_use_after_free_read+0xb3/0x143
	kunit_try_run_case+0x61/0xa0
	kunit_generic_run_threadfn_adapter+0x16/0x30
	kthread+0x176/0x1b0
	ret_from_fork+0x22/0x30

	kfence-#79: 0xffff8c3f2e2a0000-0xffff8c3f2e2a001f, size=32, cache=kmalloc-32

	allocated by task 488 on cpu 2 at 33.871326s:
	test_alloc+0xfe/0x738
	test_use_after_free_read+0x76/0x143
	kunit_try_run_case+0x61/0xa0
	kunit_generic_run_threadfn_adapter+0x16/0x30
	kthread+0x176/0x1b0
	ret_from_fork+0x22/0x30

	freed by task 488 on cpu 2 at 33.871358s:
	test_use_after_free_read+0xa8/0x143
	kunit_try_run_case+0x61/0xa0
	kunit_generic_run_threadfn_adapter+0x16/0x30
	kthread+0x176/0x1b0
	ret_from_fork+0x22/0x30

	CPU: 2 PID: 488 Comm: kunit_try_catch Tainted: G B 5.13.0-rc3+ #7
	Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.14.0-2 04/01/2014
	==================================================================

	KFENCE also reports on invalid frees, such as double-frees::

	==================================================================
	BUG: KFENCE: invalid free in test_double_free+0xdc/0x171

	Invalid free of 0xffff8c3f2e2a4000 (in kfence-#81):
	test_double_free+0xdc/0x171
	kunit_try_run_case+0x61/0xa0
	kunit_generic_run_threadfn_adapter+0x16/0x30
	kthread+0x176/0x1b0
	ret_from_fork+0x22/0x30

	kfence-#81: 0xffff8c3f2e2a4000-0xffff8c3f2e2a401f, size=32, cache=kmalloc-32

	allocated by task 490 on cpu 1 at 34.175321s:
	test_alloc+0xfe/0x738
	test_double_free+0x76/0x171
	kunit_try_run_case+0x61/0xa0
	kunit_generic_run_threadfn_adapter+0x16/0x30
	kthread+0x176/0x1b0
	ret_from_fork+0x22/0x30

	freed by task 490 on cpu 1 at 34.175348s:
	test_double_free+0xa8/0x171
	kunit_try_run_case+0x61/0xa0
	kunit_generic_run_threadfn_adapter+0x16/0x30
	kthread+0x176/0x1b0
	ret_from_fork+0x22/0x30

	CPU: 1 PID: 490 Comm: kunit_try_catch Tainted: G B 5.13.0-rc3+ #7
	Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.14.0-2 04/01/2014
	==================================================================

	KFENCE also uses pattern-based redzones on the other side of an object's guard
	page, to detect out-of-bounds writes on the unprotected side of the object.
	These are reported on frees::

	==================================================================
	BUG: KFENCE: memory corruption in test_kmalloc_aligned_oob_write+0xef/0x184

	Corrupted memory at 0xffff8c3f2e33aff9 [ 0xac . . . . . . ] (in kfence-#156):
	test_kmalloc_aligned_oob_write+0xef/0x184
	kunit_try_run_case+0x61/0xa0
	kunit_generic_run_threadfn_adapter+0x16/0x30
	kthread+0x176/0x1b0
	ret_from_fork+0x22/0x30

	kfence-#156: 0xffff8c3f2e33afb0-0xffff8c3f2e33aff8, size=73, cache=kmalloc-96

	allocated by task 502 on cpu 7 at 42.159302s:
	test_alloc+0xfe/0x738
	test_kmalloc_aligned_oob_write+0x57/0x184
	kunit_try_run_case+0x61/0xa0
	kunit_generic_run_threadfn_adapter+0x16/0x30
	kthread+0x176/0x1b0
	ret_from_fork+0x22/0x30

	CPU: 7 PID: 502 Comm: kunit_try_catch Tainted: G B 5.13.0-rc3+ #7
	Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.14.0-2 04/01/2014
	==================================================================

	For such errors, the address where the corruption occurred as well as the
	invalidly written bytes (offset from the address) are shown; in this
	representation, '.' denote untouched bytes. In the example above ``0xac`` is
	the value written to the invalid address at offset 0, and the remaining '.'
	denote that no following bytes have been touched. Note that, real values are
	only shown if the kernel was booted with ``no_hash_pointers``; to avoid
	information disclosure otherwise, '!' is used instead to denote invalidly
	written bytes.

	And finally, KFENCE may also report on invalid accesses to any protected page
	where it was not possible to determine an associated object, e.g. if adjacent
	object pages had not yet been allocated::

	==================================================================
	BUG: KFENCE: invalid read in test_invalid_access+0x26/0xe0

	Invalid read at 0xffffffffb670b00a:
	test_invalid_access+0x26/0xe0
	kunit_try_run_case+0x51/0x85
	kunit_generic_run_threadfn_adapter+0x16/0x30
	kthread+0x137/0x160
	ret_from_fork+0x22/0x30

	CPU: 4 PID: 124 Comm: kunit_try_catch Tainted: G W 5.8.0-rc6+ #7
	Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.13.0-1 04/01/2014
	==================================================================

	DebugFS interface
	~~~~~~~~~~~~~~~~~

	Some debugging information is exposed via debugfs:

	* The file ``/sys/kernel/debug/kfence/stats`` provides runtime statistics.

	* The file ``/sys/kernel/debug/kfence/objects`` provides a list of objects
	allocated via KFENCE, including those already freed but protected.

	Implementation Details
	----------------------

	Guarded allocations are set up based on the sample interval. After expiration
	of the sample interval, the next allocation through the main allocator (SLAB or
	SLUB) returns a guarded allocation from the KFENCE object pool (allocation
	sizes up to PAGE_SIZE are supported). At this point, the timer is reset, and
	the next allocation is set up after the expiration of the interval.

	When using ``CONFIG_KFENCE_STATIC_KEYS=y``, KFENCE allocations are "gated"
	through the main allocator's fast-path by relying on static branches via the
	static keys infrastructure. The static branch is toggled to redirect the
	allocation to KFENCE. Depending on sample interval, target workloads, and
	system architecture, this may perform better than the simple dynamic branch.
	Careful benchmarking is recommended.

	KFENCE objects each reside on a dedicated page, at either the left or right
	page boundaries selected at random. The pages to the left and right of the
	object page are "guard pages", whose attributes are changed to a protected
	state, and cause page faults on any attempted access. Such page faults are then
	intercepted by KFENCE, which handles the fault gracefully by reporting an
	out-of-bounds access, and marking the page as accessible so that the faulting
	code can (wrongly) continue executing (set ``panic_on_warn`` to panic instead).

	To detect out-of-bounds writes to memory within the object's page itself,
	KFENCE also uses pattern-based redzones. For each object page, a redzone is set
	up for all non-object memory. For typical alignments, the redzone is only
	required on the unguarded side of an object. Because KFENCE must honor the
	cache's requested alignment, special alignments may result in unprotected gaps
	on either side of an object, all of which are redzoned.

	The following figure illustrates the page layout::

	---+-----------+-----------+-----------+-----------+-----------+---
	\| xxxxxxxxx \| O : \| xxxxxxxxx \| : O \| xxxxxxxxx \|
	\| xxxxxxxxx \| B : \| xxxxxxxxx \| : B \| xxxxxxxxx \|
	\| x GUARD x \| J : RED- \| x GUARD x \| RED- : J \| x GUARD x \|
	\| xxxxxxxxx \| E : ZONE \| xxxxxxxxx \| ZONE : E \| xxxxxxxxx \|
	\| xxxxxxxxx \| C : \| xxxxxxxxx \| : C \| xxxxxxxxx \|
	\| xxxxxxxxx \| T : \| xxxxxxxxx \| : T \| xxxxxxxxx \|
	---+-----------+-----------+-----------+-----------+-----------+---

	Upon deallocation of a KFENCE object, the object's page is again protected and
	the object is marked as freed. Any further access to the object causes a fault
	and KFENCE reports a use-after-free access. Freed objects are inserted at the
	tail of KFENCE's freelist, so that the least recently freed objects are reused
	first, and the chances of detecting use-after-frees of recently freed objects
	is increased.

	If pool utilization reaches 75% (default) or above, to reduce the risk of the
	pool eventually being fully occupied by allocated objects yet ensure diverse
	coverage of allocations, KFENCE limits currently covered allocations of the
	same source from further filling up the pool. The "source" of an allocation is
	based on its partial allocation stack trace. A side-effect is that this also
	limits frequent long-lived allocations (e.g. pagecache) of the same source
	filling up the pool permanently, which is the most common risk for the pool
	becoming full and the sampled allocation rate dropping to zero. The threshold
	at which to start limiting currently covered allocations can be configured via
	the boot parameter ``kfence.skip_covered_thresh`` (pool usage%).

	Interface
	---------

	The following describes the functions which are used by allocators as well as
	page handling code to set up and deal with KFENCE allocations.

	.. kernel-doc:: include/linux/kfence.h
	:functions: is_kfence_address
	kfence_shutdown_cache
	kfence_alloc kfence_free __kfence_free
	kfence_ksize kfence_object_start
	kfence_handle_page_fault

	Related Tools
	-------------

	In userspace, a similar approach is taken by `GWP-ASan
	<http://llvm.org/docs/GwpAsan.html>`_. GWP-ASan also relies on guard pages and
	a sampling strategy to detect memory unsafety bugs at scale. KFENCE's design is
	directly influenced by GWP-ASan, and can be seen as its kernel sibling. Another
	similar but non-sampling approach, that also inspired the name "KFENCE", can be
	found in the userspace `Electric Fence Malloc Debugger
	<https://linux.die.net/man/3/efence>`_.

	In the kernel, several tools exist to debug memory access errors, and in
	particular KASAN can detect all bug classes that KFENCE can detect. While KASAN
	is more precise, relying on compiler instrumentation, this comes at a
	performance cost.

	It is worth highlighting that KASAN and KFENCE are complementary, with
	different target environments. For instance, KASAN is the better debugging-aid,
	where test cases or reproducers exists: due to the lower chance to detect the
	error, it would require more effort using KFENCE to debug. Deployments at scale
	that cannot afford to enable KASAN, however, would benefit from using KFENCE to
	discover bugs due to code paths not exercised by test cases or fuzzers.