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 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.

bool is_kfence_address(const void *addr)

check if an address belongs to KFENCE pool

Parameters

const void *addr

address to check

Return

true or false depending on whether the address is within the KFENCE object range.

Description

KFENCE objects live in a separate page range and are not to be intermixed with regular heap objects (e.g. KFENCE objects must never be added to the allocator freelists). Failing to do so may and will result in heap corruptions, therefore is_kfence_address() must be used to check whether an object requires specific handling.

Note

This function may be used in fast-paths, and is performance critical. Future changes should take this into account; for instance, we want to avoid introducing another load and therefore need to keep KFENCE_POOL_SIZE a constant (until immediate patching support is added to the kernel).

void kfence_shutdown_cache(struct kmem_cache *s)

handle shutdown_cache() for KFENCE objects

Parameters

struct kmem_cache *s

cache being shut down

Description

Before shutting down a cache, one must ensure there are no remaining objects allocated from it. Because KFENCE objects are not referenced from the cache directly, we need to check them here.

Note that shutdown_cache() is internal to SL*B, and kmem_cache_destroy() does not return if allocated objects still exist: it prints an error message and simply aborts destruction of a cache, leaking memory.

If the only such objects are KFENCE objects, we will not leak the entire cache, but instead try to provide more useful debug info by making allocated objects “zombie allocations”. Objects may then still be used or freed (which is handled gracefully), but usage will result in showing KFENCE error reports which include stack traces to the user of the object, the original allocation site, and caller to shutdown_cache().

void *kfence_alloc(struct kmem_cache *s, size_t size, gfp_t flags)

allocate a KFENCE object with a low probability

Parameters

struct kmem_cache *s

struct kmem_cache with object requirements

size_t size

exact size of the object to allocate (can be less than s->size e.g. for kmalloc caches)

gfp_t flags

GFP flags

Return

• NULL - must proceed with allocating as usual,

• non-NULL - pointer to a KFENCE object.

Description

kfence_alloc() should be inserted into the heap allocation fast path, allowing it to transparently return KFENCE-allocated objects with a low probability using a static branch (the probability is controlled by the kfence.sample_interval boot parameter).

size_t kfence_ksize(const void *addr)

get actual amount of memory allocated for a KFENCE object

Parameters

const void *addr

pointer to a heap object

Return

• 0 - not a KFENCE object, must call __ksize() instead,

• non-0 - this many bytes can be accessed without causing a memory error.

Description

kfence_ksize() returns the number of bytes requested for a KFENCE object at allocation time. This number may be less than the object size of the corresponding struct kmem_cache.

void *kfence_object_start(const void *addr)

find the beginning of a KFENCE object

Parameters

const void *addr

address within a KFENCE-allocated object

Return

address of the beginning of the object.

Description

SL[AU]B-allocated objects are laid out within a page one by one, so it is easy to calculate the beginning of an object given a pointer inside it and the object size. The same is not true for KFENCE, which places a single object at either end of the page. This helper function is used to find the beginning of a KFENCE-allocated object.

void __kfence_free(void *addr)

release a KFENCE heap object to KFENCE pool

Parameters

void *addr

object to be freed

Description

Requires: is_kfence_address(addr)

Release a KFENCE object and mark it as freed.

bool kfence_free(void *addr)

try to release an arbitrary heap object to KFENCE pool

Parameters

void *addr

object to be freed

Return

• false - object doesn’t belong to KFENCE pool and was ignored,

• true - object was released to KFENCE pool.

Description

Release a KFENCE object and mark it as freed. May be called on any object, even non-KFENCE objects, to simplify integration of the hooks into the allocator’s free codepath. The allocator must check the return value to determine if it was a KFENCE object or not.

bool kfence_handle_page_fault(unsigned long addr, bool is_write, struct pt_regs *regs)

perform page fault handling for KFENCE pages

Parameters

unsigned long addr

faulting address

bool is_write

is access a write

struct pt_regs *regs

current struct pt_regs (can be NULL, but shows full stack trace)

Return

• false - address outside KFENCE pool,

• true - page fault handled by KFENCE, no additional handling required.

Description

A page fault inside KFENCE pool indicates a memory error, such as an out-of-bounds access, a use-after-free or an invalid memory access. In these cases KFENCE prints an error message and marks the offending page as present, so that the kernel can proceed.

Related Tools

In userspace, a similar approach is taken by GWP-ASan. 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.

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.